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Post-conviction DNA Testing and Wrongful Conviction, Urban Institute Justice Policy Center, 2012

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F

R E S E A R C H

Post-Conviction DNA
Testing and Wrongful
Conviction

R E P O R T

John Roman, Ph.D.
(202) 261-5774
JRoman@urban.org

June 2012

Kelly Walsh, Ph.D.
(202) 261-5434
KWalsh@urban.org

Pamela Lachman
(202) 261-5514
PLachman@urban.org

Jennifer Yahner
JYahner@urban.org
Urban Institute
Justice Policy Center
2100 M St. NW
Washington, DC 20037

This project was supported by Contract No. 2008F-08165 awarded
by the National Institute of Justice, Office of Justice Programs,
U.S. Department of Justice. Points of view in this document are
those of the authors and do not necessarily represent the official
position or policies of the U.S. Department of Justice.

research for safer communities

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Justice Policy Center

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URBAN INSTITUTE
Justice Policy Center
2100 M Street NW
Washington, DC 20037
www.urban.org

© 2012 Urban Institute
This project was supported by Contract No. 2008F-08165 awarded by the National Institute of
Justice. The National Institute of Justice is a component of the Office of Justice Programs, which
also includes the Bureau of Justice Statistics, the Bureau of Justice Assistance, the Office of Juvenile
Justice and Delinquency Prevention, and the Office for Victims of Crime. Points of view or
opinions in this document are those of the authors and do not represent the official position or
policies of the United States Department of Justice, the Urban Institute, its trustees, or its funders.
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Acknowledgements
The Post-Conviction DNA and Wrongful Conviction Project was funded by the National Institute
of Justice, Office of Justice Programs, U.S. Department of Justice. The authors are grateful to
Bethany Backes, Katharine Browning, Eric Martin, and Carrie Mulford for their guidance and
assistance. We also wish to thank the staff of the Virginia Department of Forensic Science, especially
Brad Jenkins and Deborah Collard, for their support during our data collection phase. At the Urban
Institute we would like to thank our project team and report reviewers, including Douglas GilchristScott, P. Mitchell Downey, Joshua Markman, and Carey Nadeau. Finally, Rayanne Hawkins, Shalyn
Johnson, and Katie Johnson were irreplaceable in their assistance bringing this project to
completion.

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Table of Contents 
Glossary .............................................................................................................................................................. vi 
Executive Summary ........................................................................................................................................... 1 
What this report can and cannot say about wrongful conviction .......................................................... 4 
What is wrongful conviction? .......................................................................................................................... 8 
What has previous research determined contributes to wrongful convictions? .................................. 8 
Eyewitness Identification and Informants ............................................................................................ 9 
Forensic Evidence .................................................................................................................................... 9 
Confessions ............................................................................................................................................... 9 
How does post-conviction DNA testing detect wrongful convictions? .............................................10 
The Virginia model of post-conviction DNA testing relief ..................................................................11 
Virginia in the 1970s and 1980s ................................................................................................................13 
Data ....................................................................................................................................................................14 
Case Selection ..............................................................................................................................................14 
Data Collection .......................................................................................................................................15 
Coding Schema .......................................................................................................................................15 
Quality Control ............................................................................................................................................17 
Court Data Collection ............................................................................................................................17 
County Data Collection .........................................................................................................................18 
Data Limitations ..........................................................................................................................................18 
Generalizability .......................................................................................................................................18 
Omitted Variables ...................................................................................................................................19 
Missingness ..............................................................................................................................................19 
Measures ............................................................................................................................................................20 
Post-Conviction DNA Testing Variables ................................................................................................20 
Preconviction Forensic Testing Variables ...............................................................................................21 
Case Characteristics.....................................................................................................................................22 
Convicted Offender/Victim Demographics ...........................................................................................23 
Conviction County Characteristics (Virginia) .........................................................................................23 
Methodology .....................................................................................................................................................24 
Dropping Nonsexual Assault Homicide Convictions ...........................................................................25 
Logistic Regressions ....................................................................................................................................25 
Multinomial/Sequential Logistic Regression/Propensity Score Analysis ...........................................26 
Clustering ......................................................................................................................................................27 
Results................................................................................................................................................................27 
What proportion of convictions had determinate DNA testing results? ............................................28 
What factors distinguish convictions with determinate and indeterminate DNA testing results? ..30 
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What model predicts whether DNA testing results on a case will lead to determinate or
indeterminate conclusions about conviction? .........................................................................................36 
What factors distinguish inculpatory sexual assault convictions from all convictions with
exculpatory evidence (either currently insufficient or supportive of exoneration)? ..........................38 
What model predicts whether determinate DNA testing results on a conviction will be
exculpatory or inculpatory regarding a convicted offender’s actual innocence? ................................46 
Does the same model predict exculpatory DNA testing results supporting exoneration, as
opposed to inculpatory results? .................................................................................................................50 
Case Studies ......................................................................................................................................................52 
Case Study #1: Exoneration ......................................................................................................................52 
Case Study #2: Exoneration ......................................................................................................................52 
Case Study #3: Exoneration ......................................................................................................................53 
Case Study #4: Exoneration ......................................................................................................................53 
Case Study #5: May Be Exculpatory and Supporting/Inculpatory .....................................................53 
Case Study #6: May Be Exculpatory and Supporting............................................................................54 
Case Study #7: May Be Exculpatory and Supporting/Inculpatory/Indeterminate ..........................54 
Case Study #8: May Be Exculpatory but Insufficient ...........................................................................54 
Discussion .........................................................................................................................................................55 

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List of Figures and Tables
Figure 1. The VA Model of Post-Conviction DNA Testing ....................................................................11 
Figure 2. Decision Tree: Case Coding Tool.................................................................................................16 
Table 1. Individual Cases and Individual Convictions ................................................................................. 5 
Table 2. Outcome of DNA Testing Results, by Sexual Assault Status ...................................................... 6 
Table 3. Comparison of UI and VA DFS Case Designations...................................................................17 
Table 4. Outcome of DNA Testing Results by Sexual Assault Status .....................................................25 
Table 5. Outcome of All DNA Testing Results ..........................................................................................28 
Table 6. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Convictions: PostConviction DNA Testing ...............................................................................................................................31 
Table 7. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Cases:
Preconviction Forensic Testing .....................................................................................................................32 
Table 8. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Convictions: Case
Characteristics...................................................................................................................................................33 
Table 9. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Convictions:
Convicted Offender/Victim Demographics................................................................................................34 
Table 10. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Convictions:
Conviction County Characteristics ................................................................................................................35 
Table 11. Multivariate Logit Model Predicting Determinate DNA Testing Results .............................36 
Table 12. Final Multivariate Logit Model Predicting Determinate DNA Testing Results ...................37 
Table 13. Bivariate Comparison of Exculpatory and Inculpatory Sexual Assault Convictions: PostConviction DNA Testing Variables ..............................................................................................................39 
Table 14. Bivariate Comparison of Exculpatory and Inculpatory Sexual Assault Convictions:
Preconviction Forensic Testing Variables ....................................................................................................40 
Table 15. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and Inculpatory
Results: Case Characteristics ..........................................................................................................................42 
Table 16. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and Inculpatory
Results: Convicted offender/Victim Demographics ..................................................................................43 
Table 17. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and Inculpatory
Results: Conviction County Characteristics .................................................................................................45 
Table 18. Multivariate Logit Models Predicting Exculpatory DNA Testing Results ............................47 
Table 19. Final Multivariate Logit Model Predicting Exculpatory DNA Testing Results ....................49 
Table 20. Final Multivariate Logit Model Predicting Exculpatory DNA Testing Results, Estimated
Only on Convictions with Exculpatory Results that Support Exoneration (versus Inculpatory) .......51 

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Glossary
ABO typing - Testing blood or other physiological fluids to determine if the person they came
from carries the A antigen (Type A), the B antigen (Type B), both (Type AB), or the H antigen
(Type O).
Akaike information criterion (AIC) corrected - A diagnostic tool used in statistics to reflect how
well a model fits the observed data. When comparing multiple models, the best fitting model will
have the lowest AIC value.
Bivariate comparison - A model that tests the significance of two variables: one predictor
(independent variable) and one outcome (dependent variable).
Determinate - Allowing a conclusion to be drawn as to whether the person convicted was a
possible source of the DNA developed from the original evidence.
DNA profile - The final product of DNA testing as it was performed in this study. The profile is a
series of numbers that describe a person’s DNA at specific locations (loci) on the genome. A full
profile is produced when testing yields numbers at every targeted location. A partial profile may
occur when data are generated only a few loci. In general, the more loci represented in a profile, the
stronger the association or “match” that can be made.
Enzyme typing - A generic term used in this study that includes all non-ABO typing systems,
including other antigen markers, protein markers (Hb, Hp), and actual enzyme markers (such as
PGM, Esd, EAP). In the pre-DNA era, the more types used to link questioned and known items,
the higher the likelihood that they came from the same source.
Exculpatory - Evidence that reduces certainty that a person committed a criminal act.
Exculpatory and supportive of exoneration - The results of the DNA testing that exclude the
convicted offender as the source of DNA developed from old evidence. This result would support a
claim of wrongful conviction. However, this alone may not be sufficient to prove wrongful
conviction.
Exculpatory but insufficient for exoneration - The DNA testing eliminated the convicted
offender as the source of DNA developed from old evidence. However, due to the context of the
case, this result does not support a claim of wrongful conviction.
Exoneration - Applies to a person who has been legally exonerated by the state of Virginia as of
April 1, 2012.
Inculpatory - Describes evidence that adds strength to the assertion that a person committed a
criminal act.
Indeterminate - (1) No new DNA evidence was developed in the case or (2) no conclusion can be
drawn about the source of DNA evidence that was developed.
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Individualizing - Establishing uniqueness or the source of questioned evidence.
Multivariate logit - A statistical model that evaluates the covariation of multiple independent
variables and one binary dependent variable.
Nagelkerke R-square - A value between 0 and 1 that describes how much of the variation in the
dependent variable is explained by the statistical model. As the value approaches 1, more variation is
explained and the better the model fits the observed data. A Nagelkerke R-square value of 1 means
the model perfectly fits the data.
Physical evidence recovery kit/“PERK” - This is the term used for the swabs and other materials
used to collect physical evidence (both reference and questioned) from persons of interest in a case.
These kits were frequently used to collect biological evidence from suspects and victims of sexual
assault.
Probative - Information that tends to prove an assertion.
Questioned evidence - Physical evidence whose true source is unknown (e.g., a bloodstain found
on a wall at a crime scene).
Reference sample - Physical evidence that has been collected directly from a person (e.g., blood
drawn from a suspect or a cheek swab from a victim).
Statistical significance - Describes a relationship between two variables in which the difference in
means is large enough that it is unlikely to have occurred by chance.

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Executive Summary
Forensic evidence, particularly fingerprints, has been used for more than a century to aid law
enforcement investigations. However, only in the past decade has the use of deoxyribonucleic acid
(DNA) testing to include or eliminate suspects and exonerate those convicted in serious crimes
become relatively common. DNA evidence is said to be individualizing because of its power to link
a person to a criminal incident. And unlike fingerprints, the probability that questioned evidence
from a crime scene matches DNA from a known person can be calculated. In past decades, the
investigation of serious crimes that led to a conviction typically did not use individualizing forensic
biological evidence such as DNA. Thus, it is possible that some individuals convicted in serious
person crimes (sexual assault and homicide) would have been eliminated by a forensic analysis more
discriminating than what was available at the time. To estimate the rate of such possible wrongful
convictions and to identify their predictors, the National Institute of Justice (NIJ) in the U.S.
Department of Justice funded retrospective DNA testing of physical evidence in cases where there
was a conviction of a sexual assault or homicide and physical evidence was retained.
Two states participated in this research. In Arizona, every eligible prisoner was informed
about the program and was given the opportunity to request DNA testing of physical evidence.
Testing was performed when physical evidence could be located and if a review of the case deemed
that evidence to be probative in the conviction. The Arizona site thus provides a case study that can
be used to qualitatively evaluate how often a voluntary program leads to detection of wrongful
conviction. The results of the Arizona experiment are described in a separate report.
In Virginia, a cohort of 634 cases of sexual assault and/or homicide dating from 1973 to
1987 was discovered to have retained physical evidence. Since most state legislation that requires
evidence storage was enacted in the post-DNA era, it is likely that many states have not preserved
physical evidence for cases from the pre-DNA era. Therefore, the evidence in the Virginia cases
provides a unique opportunity to determine how often DNA testing can be used to identify
wrongful convictions. The results can be generalized (with caveats) because the physical evidence
was retained for reasons unrelated to the case outcome, and the cases were assigned to the serologist
who retained the evidence in a way that did not introduce bias.
Once cases were found to meet the NIJ eligibility requirements (retained physical evidence,
conviction of a sexual assault and/or homicide), the evidence was sent to a private lab for DNA
analysis. The goal of this DNA testing was to develop a profile from questioned evidence, generally
from the crime scene, and compare it to profiles of known persons developed from the original
evidence or stored in a database.1 From these comparisons, a determination can be made whether

Associative physical evidence is either questioned (Q) or reference (K). When evidence is questioned, its true source is
unknown. For example, when a bloodstain is found at a crime scene, investigators do not know whose blood has been
found. To make that determination, it must be compared to a reference sample. Reference samples are evidence
collected directly from persons of interest (e.g., suspects, victims, and/or consensual partners). DNA profiles from
questioned evidence are compared with DNA profiles from reference samples to determine if a suspect, victim, or other
known person can be included or excluded as the source of that questioned evidence.
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that evidence is indeterminate,2 inculpatory, or exculpatory.3 The Virginia cases, all of which
occurred before DNA evidence testing was readily available, can therefore be used to answer a
critical policy question: “What proportion of convicted offenders in serious person crimes with
retained forensic evidence could be exonerated if that evidence were DNA tested?”
To answer this question, the Urban Institute (UI) conducted a retrospective study using
observational data from the Virginia post-conviction DNA analyses to estimate the rate at which
defendants are wrongly convicted and to identify case attributes associated with such wrongful
convictions. Toward this end, the Virginia data, which were contained in files maintained by the
Virginia Department of Forensic Science (DFS), were made available to UI researchers. All files
contained information about the pre- and post-conviction forensic facts of the case, including results
of the original forensic testing on the physical evidence, as well as results of the contemporary DNA
analysis. Additionally, most files contained information about other basic case attributes, such as the
charge and jurisdiction of the crime and demographic information about the convicted offender and
other known suspects and victims. These data will serve two purposes.


First, we will use these data to determine whether the results of Virginia’s DNA testing would
support exoneration of a convicted defendant, inculpate the defendant, or be insufficient4 to
change the outcome of the case. We note that it is critical to keep in mind that our data
collection was largely limited to the DFS forensic files, and because of this, we must assume that
the forensic evidence is sufficiently probative to make such a determination for each conviction.
However, it is possible that other nonforensic facts of the case that are not available to us may lead
to a different conclusion. For instance, DNA tests from a questioned stain on clothing
recovered from a sexual assault case might eliminate the convicted offender as the source of the
stain, which we would label as supportive of exoneration. However, if more information about
the case was available, other facts of the case may prove the clothing was unrelated to the
assault. In that case, what appears to be strong evidence in support of exoneration is actually not
probative. Since our data collection was limited to data in the DFS forensic files, we might not
be able to observe those additional facts.

DNA testing results are indeterminate for four reasons: (1) questioned evidence from a crime scene could not be
compared with a reference sample because there was no reference sample available for the convicted offender; (2) there
were no DNA profiles obtained from any questioned evidence, only DNA obtained from a victim or offender reference
sample; (3) technology applied to the DNA analysis of questioned evidence could not develop a profile because the
quantity of DNA was below detectable levels; and (4) testing did not yield a DNA profile because no DNA was ever
present in the biological evidence that was collected at the crime scene.
2

3 As is discussed later in the report, a finding that a suspect is eliminated as the source of questioned evidence is not
synonymous with exoneration because that evidence might not be probative (i.e., does not point to guilt or innocence).
For example, a profile from questioned evidence found on the victim may have come from the victim and not the
suspect, which still does not address the suspect’s guilt or innocence. Even when questioned evidence includes the
convicted offender, it is a necessary but not sufficient condition for exoneration. Other facts of the case (statements,
eyewitnesses, etc.) must also be considered before a convicted offender can be exonerated. For instance, finding a DNA
profile matching the suspect at a crime scene is not sufficient to conclude guilt if the suspect had a legitimate reason to
be there at some other time.

DNA testing would be insufficient to change the outcome of a case if (1) results of testing were indeterminate or (2)
results were exculpatory but other known case characteristics make this result not relevant.
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Second, we will use these data to identify associations between case characteristics and the
likelihood that DNA testing would produce determinate results and support exoneration of a
convicted defendant. These findings can be used by states to prioritize closed cases for postconviction DNA analysis. If those attributes include factors that exist today, policy
recommendations can be made to avoid new wrongful convictions.

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What this report can and cannot say about wrongful conviction
The data available for this study likely provide the best opportunity to date to understand the rate of
wrongful conviction and the correlates of wrongful conviction. As described further later in the
report, the data developed by the Virginia DFS appear to be from an unbiased sample of homicides
and sexual assaults where an offender was convicted and physical evidence was retained over a
period of about 15 years.5 Though these cases were assigned to a single forensic examiner, these
crimes, investigations, and prosecutions occurred in counties throughout the state of Virginia.
Interviews with DFS supervisors found that there were no differences in caseload across forensic
examiners during this period. Thus, we believe that our data set includes cases that are equivalent to
other serious person crimes in the state of Virginia from 1973 to 1987.
However, there are serious limitations to the data set as presently constituted. First, the DFS
files did not always contain sufficient information about the context of the physical evidence and are
missing many nonforensic facts that may be critical to ultimate determination of the probative value
of DNA testing results. In fact, as a pilot test, we visited three Virginia county courthouses and
found that sufficient, nonforensic data still exist in public court records to allow for more precise
designation of case outcomes. However, for technical reasons the research contract could not be
extended to allow visits to the 94 counties with a convicted offender in this data set.
The second limitation of this data set is that in two-thirds of the convictions6 the DNA
analysis did not produce a DNA profile or no forensic determinations about wrongful conviction
could be made.7 If the likelihood that a case has determinate results is not related to the probability
of wrongful conviction, then we could generalize results from convictions with determinate findings
to convictions with indeterminate findings. However, we found that convictions for crimes
involving any sexual assault were more likely to yield determinate results when compared to
convictions for nonsexual assault homicide, simply because of the presence of a victim or suspect
physical evidence recovery kit (PERK), which often yielded a DNA profile. Thus, we cannot
interpolate from sexual assault convictions with determinate results to nonsexual assault homicide
convictions with indeterminate results. These two limitations have particularly important impacts on
the way in which we estimate the rate of wrongful conviction.
Of the cases originally reviewed (more than 534,000), approximately 3,000 had retained
physical evidence; in 2,100 of those cases a suspect was identified; and 740 cases had at least one
suspect convicted of a felony. Of those, 634 cases with 715 convictions (62 cases had multiple
suspects) were NIJ eligible based on crime type (homicide, sexual assault) and a conviction. The
relationship between case and number of convictions is illustrated in Table 1.

The offense dates in these cases occurred from 1973 to 1987; DNA testing was conducted from 2009 to 2011.
Convictions were obtained by guilty plea, jury trial and judge trial; however, DFS data were incomplete and thus the
type of disposition is missing for many cases.
7 As is discussed later, only 8 percent of convictions for nonsexual assault homicide produced a determinate finding.
More than half (54 percent) of sexual assault cases, including those ending in homicide, resulted in a determinate finding.
5
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Table 1. Individual Cases and Individual Convictions
Number of Convictions in a Single Case
Number of Cases
1
572
2
48
3
10
4
3
5
1
Total
634

Number of Convictions
572
96
30
12
5
715

DNA testing produced a determinate outcome for 230 of these cases, in which there were
250 convicted offenders. In 56 of those convictions the convicted offender was eliminated as the
source of DNA evidence, and for 38 convictions that elimination supported exoneration.
Thus, we find that in Virginia cases resulting in a convicted offender between 1973 and 1987
where evidence was retained in an unbiased sample of 715 homicides and sexual assault
convictions—


The convicted offender is eliminated as a contributor for a probative evidence item in 8
percent (n=56) of convictions.8



The convicted offender is eliminated as a contributor for a probative evidence item, and that
elimination is supportive of exoneration, in 5 percent (n=38) of convictions.

For nonsexual assault homicide cases, a determinate finding about a convicted offender being a
source of a DNA profile was reached in only 23 out of 293 convictions (8 percent), making it too
rare to make declarative statements about the likelihood of potential wrongful conviction in those
homicide convictions.
We find that DNA testing of items in these cases leads to a determinate conclusion in more
than half of the sexual assault convictions (including homicides with a sexual assault). Thus, we
focus much of our analysis on the sexual assault offenses. We find that in convictions in Virginia
between 1973 and 1987 where evidence was retained in a sample of 422 convictions for sexual
assault—


The convicted offender was eliminated as the source of questioned evidence in 40 out of
422 convictions (9 percent).9



The convicted offender was eliminated as the source of questioned evidence in 33 out of
422 convictions (8 percent) and that elimination was supportive of exoneration.



The convicted offender was eliminated as the source of questioned evidence in 40 out of
227 convictions (18 percent) where a determination could be made from the DNA
analysis.10

(exculpatory but insufficient n=18) + (exculpatory supporting exoneration n=38) = 56.
Where sexual assault = yes, (exculpatory but insufficient n=7) + (exculpatory supporting exoneration n=33) = 40.
10 (Any sexual assault n=422) – (indeterminate sexual assaults n=195) = 227.
8
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The convicted offender was eliminated as the source of questioned evidence in 33 out of
227 convictions (15 percent) where a determination could be made from the DNA
analysis, and that elimination was supportive of exoneration.

The two most important numbers in the bullets above show the rate at which convicted offenders
were eliminated as the source of questioned evidence and that elimination was supportive of
exoneration. This occurs for 8 percent of all sexual assault convictions in the sample and for 15
percent of all sexual assault convictions where a determinate finding was made. We note again that
additional facts about the case not included in the forensic file may ultimately include the convicted
offender. However, given that these are sexual assault cases where the profile was determined to be
male and excluded the convicted offender, we anticipate this will be relatively rare.
Table 2. Outcome of DNA Testing Results, by Sexual Assault Status
Sexual Assault
Outcome
Indeterminate

Inculpatory

Exculpatory but insufficient

Exculpatory supporting exoneration

Total

Count
% of
Column
Count
% of
Column
Count
% of
Column
Count
% of
Column
Count
% of
Column

No
270

Yes
195

Total
465

92%

46%

65%

7

187

194

2%

44%

27%

11

7

18

4%

2%

3%

5

33

38

2%

8%

5%

293

422

715

100%

100%

100%

From our data, there are several ways to calculate an estimated rate of wrongful conviction,
and all are unsatisfactory. The first option is to divide the number of exculpatory outcomes by the
total number of cases considered (over 534,000 case files were originally reviewed). We did not use
this approach given that the vast majority of cases were not subjected to DNA testing because there
was no conviction and no physical evidence retained (and we are not attempting to generalize
findings in this study to nonfelony convictions or to cases in which no physical evidence was
collected or retained).11
Given the potential inaccuracy of an estimate of any rate of wrongful conviction, we provide
two statistics as an alternative, both based on the actual numbers observed in this data:

Additionally, it would be incorrect to calculate a rate when the units in the numerator (convictions) are different than
the denominator (cases). A single case could result in multiple convictions.

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1) The rate at which convictions for serious person crimes and retained evidence yielded a
DNA profile and the convicted offender was eliminated as the source (56/715 or 7.8 percent); and
2) The rate at which convictions for serious person crimes and retained evidence yielded a
DNA profile and the convicted offender was eliminated, and that elimination appears to be
probative evidence that supports exoneration (38/715 or 5.3 percent).
Finally, we note that despite our concerns about calculating an estimated rate of wrongful
conviction solely from the 227 convictions for sexual assault with determinate results, we
nevertheless conduct several analyses to look at the association between the case attributes of these
227 convictions and whether the DNA analysis was inculpatory or exculpatory. While we have the
same concerns about whether unobserved heterogeneity may lead to spurious conclusions about
these relationships, we believe these findings are an important starting point for the field to
investigate old cases for wrongful conviction and to prevent future wrongful conviction. We do not
make any causal claims about these relationships: Rather, we see them as clues in the hunt for
innocence.

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What is wrongful conviction?
Conviction may be classified as wrongful for one of two reasons (1) the person convicted is factually
innocent of the charges, or (2) there were procedural errors that violated the convicted person’s
rights. In this study, since DNA evidence is the tool used to detect wrongful convictions, we are
solely concerned with those where factual innocence is the issue. Post-conviction DNA testing
cannot be used to detect erroneous convictions due to reversible procedural errors.
A review of the wrongful conviction literature (Gould and Leo 2010) finds that several
studies put the upper bound rate of wrongful conviction between 3 percent and 5 percent. The most
conservative estimate was proffered by Scalia (Kansas v. March, 278 Kan. 520, 2006) and Marquis
(2006), who took the 340 known wrongful felony convictions from a previous study (Gross 2005),
multiplied by a factor of 10 and divided by all felony convictions from the same time frame (Gould
and Leo 2010). The resulting rate, 0.027 percent, is criticized as much too conservative given that
the numerator only represents detected wrongful convictions where DNA was used to evaluate
culpability, 95 percent of which were sexual assaults or murders. The denominator, all felony
convictions, has a different distribution of crime types that included a much smaller percentage of
rapes and murders.
The data set in our study is better suited to determine rates of wrongful convictions than
previous works. All cases in this study were convictions for serious person crimes, from a single time
frame, where biological evidence was collected and tested in the original investigation. The postconviction DNA testing identified not just likely wrongful convictions but also rightful ones. This
provided several denominator choices that more closely resemble the convictions with exculpatory
results in convicted offender, victim, and crime characteristics. One limitation to this data set is that
it remains unknown how many of the convictions with exculpatory results of DNA testing are
actually wrongful and will result in exoneration. The media and the Innocence Project have reported
on several exonerations that are due to Virginia’s post-conviction DNA testing, which we have
reported on in the Case Studies section when such individuals were located in this study’s data set;
however, the current status of each conviction with an exculpatory finding was not available to UI
researchers through the DFS case files or via other data sources.
What has previous research determined contributes to wrongful convictions?
Until this study, previous research on wrongful convictions has been based on data known only for
cases in which the convicted offender (or others on his/her behalf) actively pursued exoneration.
Given this caveat, there is a substantial body of literature that indicates certain attributes of the
victim, offender, and crime may be associated with the likelihood that an individual is wrongly
convicted.
Garrett (2008) found that minorities were overrepresented among exonerated offenders,
given the rate at which minorities are typically convicted of murder and rape. Conners et al. (1996)
reported that most DNA exonerations occurred in cases beginning in the mid- to late 1980s, a
period when forensic DNA technology was not readily available. They also connected actualinnocence cases with short jury deliberations (the majority of which lasted less than a day) and with
prior police knowledge of the defendant. Garrett (2008) suggested that codefendants may play a part
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in wrongful conviction; for example, a defendant may only be identified through false testimony of a
codefendant, who may have been offered a reduced sentence for cooperation with the prosecution.
Eyewitness Identification and Informants
Most studies on actual innocence have found that false eyewitness testimony and faulty forensic
evidence were the leading causes of wrongful convictions (Conners et al. 1996; Garrett 2008, Gross
et al. 2005; Innocence Project web site). In the Garrett (2008) study, false eyewitness testimony
contributed to a wrongful conviction in 79 percent of his sample, while faulty forensic evidence was
present in 55 percent of wrongful convictions (a defendant could be convicted based on more than
one type of evidence, so these percentages do not sum to 100 percent). In regard to witness
misidentification, Garrett’s police records indicated many instances where an eyewitness hesitated on
the identification, did not initially correctly identify the defendant, or indicated less than 100 percent
certainty when identifying the suspect to police. Furthermore, Conners and colleagues (1996)
indicated that in murder cases, where no victim eyewitness is possible, wrongful convictions may be
made by witness misidentification placing the defendant near the scene of the crime or with the
victim. Kreimer and Rudovsky’s (2002) study on post-conviction DNA testing found that jailhouse
informants’ testimony has been well-documented as particularly unreliable
Forensic Evidence
Peterson and colleagues (1987) found that forensic evidence had an effect on conviction (but not
necessarily wrongful) in two independent ways. There was an initial effect of a case having any sort
of forensic evidence, and the additional effect of the forensic evidence linking the defendant with
the crime. Peterson and colleagues also found that when a laboratory had nonassociative forensic
results, the conviction rate was 59 percent, while if the laboratory report yielded results that
associated the defendant with the crime,12 the conviction rate was 95 percent.
Garrett (2008) reported that in wrongful convictions, some types of forensic evidence were
particularly unreliable. Specifically, bite mark and hair comparisons were particularly problematic
because their associations with a suspect are unquantifiable. Forensic evidence may be associated
with a wrongful conviction in several ways. First, the results of a forensic analysis may be unreliable
or even false if an examiner has purposefully altered data to produce a desired result. Second,
forensic evidence may rightfully create a link to the wrong person (i.e., the true perpetrator and a
person wrongfully convicted may have the same blood type). Or finally, the significance of links
created by forensic evidence could be overstated by the expert, not adequately challenged by defense
counsel, or mischaracterized in closing statements by the prosecution.
Confessions
Wrongful convictions based on false confessions make up a small proportion of total exonerations.
However, of those who falsely confess, 35 percent have a diagnosed mental illness and 39 percent
are juveniles (Garret 2008). Further, differences in false confessions across types of charges indicate
that a false confession may be more likely for a murder than for a rape, and thus the interaction
between the type of charge and whether or not there was a confession could be particularly
important. Garrett (2008) shows that within his sample, only 6 percent of rape exonerees had a false
confession, whereas 41 percent of rape-homicide exonerees had a false confession.
12

In other words, the suspect could not be eliminated as the source of some physical evidence.

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How does post-conviction DNA testing detect wrongful convictions?
The DNA molecule stores the genetic code for the functions of the human body and is present in
almost every cell. Each person’s DNA sequence is unique13; however, the processes used by labs to
analyze DNA for criminal justice purposes do not typically reveal the DNA sequence itself. Instead,
the information developed, shared with law enforcement ,and possibly uploaded to a database is
called the DNA profile. When a full DNA profile is developed, there is little doubt about the
identity of an individual. The profile is a series of numbers, each one of which represents the
number of repeated patterns of DNA at a particular location on the DNA molecule. The profiles,
produced from forensic evidence, are compared to profiles produced from known persons or
profiles from other crime scene evidence in order to make associations. The high specificity of these
associations comes from the frequency statistics associated with each number (or allele) in the
profile.
The use of DNA evidence as an investigative tool has its roots in the pioneering work of
Alec Jeffreys in 1985 (Jeffreys, Wilson, and Thein 1985; Jobling and Gill 2004). The first DNAbased criminal investigation, in 1986 in Leicestershire, England, used Jeffreys’s restriction fragment
length polymorphism (RFLP) technique (Friedman 1999). While RFLP-based methods were
effective, they were slow and required large amounts of intact DNA (Friedman 1999). Due to these
limitations and technical advances in the 1990s, RFLP processing was gradually displaced by
superior methods based on the polymerase chain reaction (PCR) (Friedman 1999). PCR-based
methods produce multiple copies of the DNA pieces for analysis. A PCR-based method that
analyzes polymorphic regions of DNA called short tandem repeats (STRs) is now the preferred
method of DNA identification (Wise 2004).
Forensic STR processing of DNA uses predefined, specific locations on the human genome
that are noncoding and therefore do not influence a person’s physical or biological traits. Therefore,
data produced through forensic DNA processing do not reveal any expressed genetic information or
physical characteristics of a person.14 They merely act as an identifying mechanism that forensic
scientists use to determine if there is an association between the evidence sample and a particular
person. Once these associations are made,15 they are used by law enforcement agencies to aid
investigations and prosecutions. The impact of the DNA association on any criminal investigation,
and in any investigation of a wrongful conviction, is dependent on the probative value of the
evidence and the context of the investigation.
Because sex offenders nearly always leave biological evidence behind, DNA analysis can be
an especially powerful tool for the criminal investigation and prosecution of sexual assault cases
(Weedn and Hicks 1998). The effectiveness of DNA in those cases has led to efforts to expand
DNA evidence collection and processing to other types of crime (Roman et al. 2009).
DNA testing was not available at the time the crimes in our data set occurred. A 1983 survey
of more than 300 crime labs in the United States (Peterson et al. 1985) shows that 75 percent of labs
analyzed hair, semen, blood, and other forensic evidence and 90 percent performed drug
With the exception of identical twins and other multiples.
The only characteristic that may be revealed is gender.
15 And quantified through the use of population statistics to generate the random match probability (RMP).The RMP is
defined as the probability that the DNA profile of a person randomly chosen from the population is the same as the
profile developed from questioned evidence (http://www.dna.gov/glossary/#E).
13
14

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examinations. A similar survey undertaken in 2002 illustrates the dramatic transformation of crime
labs since the 1990s (Hickman and Peterson 2004; Peterson and Hickman 2005). By year-end 2002,
a total of 351 publically funded crime laboratories operated in the United States (Peterson and
Hickman 2005). Approximately 61,000 requests (2 percent of new requests for forensic analysis)
were in the area of DNA analysis.
The Virginia model of post-conviction DNA testing relief
In traditional models of post-conviction DNA testing, an advocacy group or government agency
reacts to the claim of wrongful conviction made by the person convicted or others on their behalf.
Almost all relief actions (e.g., investigations, DNA testing) occur after this petition is made. As a
result, almost all cases of known wrongful conviction due to actual innocence are detected because a
person is actively making that claim. Any innocent persons who do not outwardly claim it remain
undetected. In the traditional model, DNA testing is performed near the end of a post-conviction
relief review, while in Virginia, for the convictions in this study, it was performed at the beginning.
The Virginia (VA) model of post-conviction DNA testing, shown in figure 1, is unique.
Rather than start with claims of actual innocence from living convicted offenders, the state received
funding to test all existing physical evidence that might contain DNA for serious person crimes that
resulted in conviction. The claims of actual innocence (or admittance of actual guilt) therefore did
not influence the decision to conduct DNA testing. This “test-them-all” approach to postconviction DNA testing has never been replicated by any other state. However, this novel model
emerged from activities associated with the traditional approach.
Figure 1. The VA Model of Post-Conviction DNA Testing

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In 2001, VA passed a law allowing persons convicted of a crime to have evidence that was
newly discovered or previously untested for DNA, tested. Soon thereafter, the Mid-Atlantic
Innocence Project began contacting the VA Department of Forensic Science about prisoner
petitions for post-conviction relief. The first convicted person with such a petition (who was later
pardoned by VA’s governor) led to DFS’s discovery of the retained physical evidence examined in
this study. Although most of the case evidence from the time of that first case (1982) had not been
retained, his case file included clippings of the physical evidence that the serologist in his case (Mary
Jane Burton) had included in her files.16 Upon further review, DFS discovered that this practice was
repeated in hundreds of Burton’s case files,17 and these files represent the cases included in this
study. Clippings in two other cases were tested, leading to three additional exonerations, but these
cases are not included in our data set.
Given this finding, in 2005, the governor ordered testing of all eligible convictions to see if
they could develop any additional DNA profiles and whether they led to exoneration. VA DFS
looked for cases that had evidence retained. Among the cases reviewed, an additional two
exonerations were made. At this point the governor ordered the review of all convictions where
DNA may exist but had not been tested.
VA applied for and was granted funding from NIJ for these activities. Case files were stored
in paper from across the state’s four regional labs. All cases were from 1973 to 1987, and all
534,000+ were brought to the Central Lab for review. DFS then used a number of screening criteria
to wade through the 534,000 cases. First, the case had to have physical evidence retained that could
be tested (the clippings mentioned above). This brought the number from 534,000 down to around
3,000 cases. Next, there had to be a known suspect in the case (which reduced the number of
eligible cases 3,000 to 2,100) and there had to be a felony conviction (reducing the number of
eligible cases dropped from 2,100 to 740). Finally, NIJ required that the felony conviction be for a
sexual assault, homicide, or non-negligent manslaughter, reducing the number of cases to the final
sample of 634.
To prevent additional workload pressure on the VA DFS lab, Virginia outsourced all postconviction DNA testing to a private laboratory. After the private lab’s analysis, the DFS lab
personnel reviewed the testing results and issued the final lab report (a certificate of analysis). The
laboratory processing developed DNA profiles from STRs. When necessary, differential extractions
were performed on the evidence prior to amplification. This type of extraction attempts to separate
sperm cells from nonsperm cells (like those shed by skin). During this procedure, the two extract
fractions are analyzed separately, with any male DNA more likely present in the sperm fraction. This
procedure is more laborious than traditional extractions but is generally more effective on evidence
items with a high likelihood of male/female mixtures, like those collected during a sexual assault
examination.
As noted above, NIJ required that grant funds be used only to test evidence from sexual
assaults, homicides, and cases of non-negligent manslaughter. Ultimately, 634 such cases, with 715
persons convicted for those crimes, matched these criteria. VA DFS did not contact living victims.
16 It is important to note that these clippings and all of the swabs and swatches tested in this project were already
subjected to serological testing in the 1970s and 1980s. These were not whole items with undisturbed stains. It is likely
that the action of serology testing had already removed some of the existing DNA.
17 While most of the samples were from Burton’s cases, a few were from serologists she had trained.

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It did, however, attempt to contact the convicted persons whose cases were tested, by certified
letters with postage-paid return postcards enclosed. Among the 715 persons convicted, some were
still incarcerated and some were deceased.
Virginia in the 1970s and 1980s
The criminal convictions analyzed in this report occurred in Virginia from the early 1970s through
the mid-1980s (the mean and median offense year was 1978). To provide historical context for this
analysis, in this section we present a sociodemographic profile of the state during that time. We base
this description largely on county-level data in Virginia’s County Statistics File I (1984), which we
obtained from the Interuniversity Consortium for Political and Social Research (ICPSR). As
discussed in the Data section below, these county data provide a snapshot of VA counties between
1977 and 1981 (USDOC Exports 1984). The data include information provided by the U.S. Census,
VA Department of State Police, and other local and federal government sources.
In 1978, Virginia had a population of 5.3 million, ranking as the 14th most populous state in
the U.S., with a population density of 135 people per square mile (for comparison, Virginia today
has an estimated population of 8.2 million and is ranked 12th largest in the U.S.). Average annual per
capita income in 1978 was just over $7,500, with a median annual household income of $17,475.
Virginia’s unemployment rate was relatively low, at 5 percent (the U.S. average at the time was 7
percent), though the poverty level in Virginia was more than twice that (11 percent). One-third (34
percent) of Virginians lived in rural areas (with less than 2,500 residents), and about the same share
(32 percent) rented rather than owned. Overall, just over half of Virginians (52 percent) said they
had lived in a different housing unit five years prior.
One in five Virginians were black/African American and the rest were white/Caucasian
(only 1 percent said they were Hispanic or of Spanish origin). Most (62 percent) had a high school
diploma, though more than half (52 percent) of eligible voters failed to vote in the 1980 presidential
election. As was true elsewhere in the U.S., most households (89 percent) were headed by males, and
only 6 percent were headed by single females with children. Fourteen percent of residents of the
state were between age 15 and 21, and 15 percent were unmarried males over the age of 14.
With respect to crime and safety, in 1978 in Virginia, there were 286 violent crimes per
100,000 residents, which was substantially below the national average of about 500 per 100,000.
Today, Virginia’s violent crime rate (210 per 100,000) remains roughly half the national average of
400. However, Virginia’s homicide rate (8.8 per 100,000) was about the same as the national average
(9), which is still true today, although Virginia’s current rate (4.6) and the nation’s current rate (4.8)
are almost half of what they were 34 years ago. In Virginia in 1978, there were 23 sexual assaults per
100,000 residents, which was well below the national average of 31. In 2010, reported sexual assaults
had declined only slightly in both Virginia (to 19) and nationally (27.5). The average number of
police officers per 1,000 persons was 1.5, and local Virginia governments spent approximately 5
percent of their revenue directly on police protection.
In the 1970s (and today), virtually all Virginia counties elected rather than appointed their
local sheriff and prosecuting attorney. Judges, however, were uniquely appointed by the Virginia
state legislature. From the 1960s through the 1990s, Democrats controlled the Virginia state
legislature and were thus responsible for appointing all judges during that time. Since 2000,
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Virginia’s legislature has generally (though not exclusively) been controlled by Republicans, although
there has been a Democratic governor eight of the last 12 years.
In 1978, Virginia was comprised of 96 counties and 40 independent cities (compared to 95
and 39 today, respectively). The latter group was and is largely unique to Virginia and represents
cities whose governments function independently of the counties in which they reside or which
surround them; thus, they also have independently operating courthouses.

Data
The physical evidence from the criminal convictions described in this report were tested by Virginia
DFS forensic scientist Mary Jane Burton, who worked as a forensic serologist for the state of
Virginia from 1973 to 1987, and processed biological evidence in serious criminal cases.18 As part of
her testing protocol, she attached cotton swab heads and textile clippings to the worksheets in her
hard-copy case files. Her coworkers report that she would use these clippings while testifying in
court to show the jury the exact piece of evidence that underwent serological testing. These samples,
which predated the use of DNA testing for criminal cases, were discovered in 2001. Thus, physical
evidence in Burton’s case files (and in case files of serologists whom she had trained) was retained,
while all other physical evidence from that period was returned to the originating jurisdiction and its
disposition is unknown.
All of the items tested in this study had previously been subjected to serology testing as it
was performed in the pre-DNA era. This included screening tests for blood and other physiological
fluids, species determination, ABO blood group typing, and—if sufficient material was available—
typing of other antigen, protein, or enzyme groups. However, the majority of the items tested were
subjected to screening and ABO typing alone. When successful, these tests characterized a biological
sample as type A (shared by 41 percent of the population) B (10 percent), AB (4 percent), or O (45
percent).19 Even when additional discrimination was obtained by typing other systems (enzymes,
proteins, etc.), the specificity of these tests, and therefore the links among suspect, victims, and
crime scenes, were much weaker than what is possible with modern DNA testing.
Case Selection
In 2008, the NIJ awarded the Virginia DFS funds to conduct DNA testing on the biological
evidence that Burton and others had saved. NIJ required that all cases enrolled in this study have
resulted in a conviction for murder, sexual assault, or non-negligent manslaughter. Ultimately, 634
cases resulting in 715 convictions were eligible for this study.
Because cases were identified in this way, these 634 cases should represent an unbiased
sample of serious person crimes resulting in at least one conviction in Virginia from 1973 to 1987.
Our interviews indicate that cases were assigned to forensic serologists at random. More specifically,
cases were distributed among all trained examiners rather equally, and no one examiner was
routinely assigned the most difficult (or the easiest) cases.

Some of the serology evidence in these cases was tested by other analysts that she had trained. However the vast
majority of evidence was tested by Burton.
19 DeForest, Gaensslen, and Lee (1983).
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Data Collection
For the 634 criminal cases (and 715 convictions) eligible for this NIJ study, UI researchers collected
three types of data from three separate sources:
1) Information on the physical evidence collected, submitted, and tested during the original
investigation and the post-conviction DNA testing results (collected from DFS files);
2) Information on the original investigation, case processing, and disposition, including
suspect and victim demographics (collected primarily from DFS but supplemented by visits to three
Virginia county courthouses—Alexandria, Arlington, and Fairfax); and
3) County-level sociodemographic and crime data from the 1970s and 1980s, collected from
the County Statistics File I, as downloaded from the ICPSR web site.
Coding Schema
From March 2009 to August 2011, teams of four to six UI researchers conducted 10 two-day site
visits to the VA DFS laboratory in Richmond to review eligible cases after post-conviction DNA
testing had been completed. When test results were delivered to DFS but prior to UI’s visits, DFS
staff designated cases as “Red” or “Green” depending on the results of the DNA analysis:


Red cases were those containing exculpatory DNA testing results, meaning that at least one
convicted offender was eliminated as a contributor of DNA found on questioned evidence.



Green cases were those containing either inculpatory DNA testing results, meaning a
convicted offender could not be eliminated as a contributor of DNA found on questioned
evidence, or indeterminate DNA testing results, for all convicted offenders. UI deemed the
DNA testing results “indeterminate” for one of two reasons:
o A DNA profile was developed but no conclusion could be drawn because there were
no convicted offender or victim reference samples to compare to questioned
evidence; or
o No DNA profiles of value were developed from any questioned evidence.

Given the elevated value of Red-designated cases, UI researchers devised a coding scheme that
involved recording post-conviction DNA testing results in Red cases at the sample level, meaning
separate data entries were made describing each sample of forensic evidence submitted. DNA
testing results in Green cases, alternatively, were coded at the case level, unless UI researchers
determined that a Green case in fact had potentially exculpatory evidence (in which case it was
coded at the sample level).
Ultimately, UI researchers established a more detailed method of identifying the four
possible outcomes of post-conviction DNA testing (indeterminate, inculpatory, exculpatory but
insufficient for exoneration, and exculpatory supportive of exoneration), as illustrated in Figure 2.
Notably, UI’s method was conducted at the convicted-offender level, while DFS’s designations were
conducted at the crime/case level.
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Figure 2. Coding DNA Testing Outcomes at the Convicted Offender Level (n=715)

Table 3 compares the original DFS case designations of Red and Green with the four
outcomes specified by UI researchers at the convicted offender level. In general, there was a high
correlation between DFS and UI case coding. The only sources of disparities had to do with cases of
multiple convicted offenders (e.g., a Red case contained testing results that were exculpatory for one
person but inculpatory of another), and cases designated as Red by DFS but that lacked a victim
reference sample needed to eliminate the convicted offender (in which case, UI designated the
outcome as indeterminate).
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Table 3. Comparison of UI and VA DFS Case Designations
Percent of Outcome Type
Outcome of post-conviction review (convicted offender-level) Green Case Red Case
Indeterminate
96%
4%
Inculpatory
94%
6%
Exculpatory but insufficient
17%
83%
Exculpatory supporting exoneration
0%
100%
Total
88%
12%

Total
100%
100%
100%
100%
100%

Quality Control
UI coding staff was trained on the proper use of the coding instruments and on the types of forensic
analyses conducted at the time of the original investigation. The latter ensured that UI staff would
correctly identify the forensic tests performed, both more common (e.g., ABO blood group typing)
and less common (e.g., isoenzyme typing). Additionally, VA DFS forensic biology staff was available
to answer any UI coder questions that arose concerning the original testing performed or the results
of the post-conviction DNA analysis.
A number of steps were taken to ensure the quality of the data coding, since none of the
forensic data were available electronically. After cases were coded, UI researchers conducted three
types of quality control reviews: (1) a complete review of all cases that were coded during the first
two site visits (after which the coding database was revised); (2) a complete review of cases that were
randomly selected by DFS20; and (3) a partial review (during the final site visit) of cases that were
missing data for key forensic variables. All quality control reviews were conducted on-site with all
DFS case file information available and by someone other than the original coder. Additionally,
whenever DFS initiated further DNA testing and/or DNA testing results changed, that case was
recoded. During the data-cleaning process, automated quality checks were performed to identify any
variables that were in conflict with one another. Finally, at the end of the project, DFS staff
reviewed all cases that UI coded as supporting exoneration.
Court Data Collection
After DFS data collection was completed in August 2011, a review of the data confirmed that the
complete data were generally limited to basic case information and data on forensic test results. Data
on important nonforensic case characteristics (e.g., type of counsel, trial or plea, sentence) were not
present in enough cases to allow statistical tests of association between those variables and sample
outcome designation. UI researchers undertook a pilot review of case data available from public
records held at Virginia courthouses. Unfortunately, court files from the 1970s and 1980s are not
held in a centralized location; rather, each court file is held in one of 120 circuit courts in the
jurisdiction where the case was originally prosecuted. There are no electronic records for these cases.
Prior to launching a planned statewide data collection, UI conducted a pilot study to
determine the data available at three local circuit courts—the City of Alexandria, Arlington County,
and Fairfax County. The three-court pilot study revealed that the court records included substantial
case characteristics that were not widely available in the DFS case files. However, for contractual
When preparing the files for UI researchers to code, DFS often included additional cases that had already been coded
by UI. We took this as a “random” selection of cases to recode as a quality control.
20

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reasons, UI’s evaluation could not be extended to match delays in DNA analysis, and thus data
collection was halted before the rest of the court visits could be completed. While some DFS case
files yielded information on conviction offense, sentence length and type, and method of conviction
(i.e., pled guilty vs. convicted by jury trial), the majority of the legal variables’ level of missingness
was too high for any of these variables to be used in our final quantitative analyses.
County Data Collection
To supplement the data collected from the DFS files and three-court pilot, we downloaded the
County Statistics File for Virginia from ICPSR. The file includes data for Virginia counties (and
independent cities) published in the 1983 County and City Data Book and the 1982 State and
Metropolitan Area Data Book, as well as additional previously unpublished statistics (USDOC Exports
1984). The purpose of collecting these data was to identify any jurisdiction-specific variables that
could potentially affect the case investigation and final disposition. The dates for each county
variable ranged from 1977 to 1981, which is close to our average year of the offense date for all
cases included in the data set (1978).
Data Limitations
There are three important limitations to this data set, as there would be in any quantitative
collections of this sort: generalizability, omitted variables, and missingness. We discuss these
limitations and our attempts to address them below.
Generalizability
The generalizability of this data set is limited by the age of the convictions (1973 to 1987) and the
randomness of the sample. Although we have controlled for the age of each case in the final
statistical models, this accounts for differences within the date range but does not make the data set
comparable to the present year. To explain the ramifications of this limitation, we previously
presented a comparison of Virginia to other U.S. states in the 1970s/80s and to present-day Virginia.
We note that although much has changed in the past few decades and Virginia’s violent crime rates
are currently half of what they were then, the relative rate of serious person crimes in Virginia
compared to the national average has remained largely the same. That fact alone, however, does not
allow us to generalize results from this analysis to current convictions, especially given the increased
use and awareness by offenders and police of the investigatory value of DNA evidence.
With regard to the randomness of this sample as compared to other serious person
convictions involving physical evidence at the time, interviews with DFS supervisors gave every
indication that criminal cases at the time were assigned at random to DFS forensic serologists. No
single examiner was routinely assigned cases based on the cases’ attributes (e.g., the difficulty or
timeliness of the case). As a result, there is no reason to believe that the assignment of cases to
examiners introduced any bias, and therefore we view this sample of Burton’s cases as equivalent to
other serious person crimes with biological evidence in the 1970s/80s that were assigned to other
examiners. However, as discussed at length later in the report, the sexual assaults in this sample may
over represent stranger offenses (i.e., the victim did not know the suspect prior to the sexual
assault).

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Omitted Variables
UI researchers visited three of the approximately 94 VA courthouses present in the data set. The
most critical pieces of information housed at VA courthouses, which are omitted from this data set
because of their missingness in 75 to 100 percent of the convictions, are as follows: method of
conviction (jury/bench trial or guilty plea), type of defense attorney (court-appointed or retained),
whether the offender confessed or gave incriminating statements, victim and eyewitness
identification, offender’s prior record and mental health problems, detailed description of the
criminal event, and notice of appeals and results from those appeals. We expect that at least some of
these variables have statistical relevance to the models predicting exculpatory evidence. Their
absence has two possible effects: first, it decreases our ability to explain why potential wrongful
convictions occur, and second, it leaves us uncertain as to whether the explanatory power of other
variables that we were able to test was artificially deflated (or inflated) due to correlations with
omitted but relevant variables. Beyond conducting additional visits to VA courthouses to collect
these missing data, we can do nothing statistically to control for omitted variable bias—as is the case
in most quantitative analyses.
Missingness
For the DFS data, we approached data missingness challenges from a different perspective. Because
we were relying on 30- to 40-year old case files that were preserved primarily by a single forensic
serologist, we acknowledge that we might not have been able to obtain all information on forensic
testing performed during the original investigation case. However, given the repeated mention of
several different types of forensic tests in the case files, it seemed likely that the absence of a test’s
mention meant that it was not performed in that case, rather than simply not discussed in the case
files. Therefore, for example, when there was no mention of microscopic hair analysis in a case file,
we coded that case as 0=”no hair analysis done” rather than “missing” (unknown if hair analysis was
done). We repeated this same logic, with the same degree of confidence, with regard to certain case
characteristics included in the DFS case files. Specifically, if the detailed crime descriptions made
absolutely no reference to a sexual assault (and the types of forensic tests performed on such cases
supported this classification), then we coded a case as though no sexual assault had occurred.
Similarly, if the crime description was detailed enough to discuss the offender, victim, and offense
but did not mention any presence of a relationship between the offender and victim, then the
offender was assumed to be a “stranger” (unknown to the victim prior to the day of the crime).
With regard to these and other variables, there remained as much as 27 percent missing
values for cases included in statistical analyses. There is, to our knowledge, no reasonable basis for
classifying these data as anything but “missing completely at random”; therefore, we used a complete
case analysis (listwise deletion) approach to estimation of final predictive models. When missingness
is completely random, removal of cases that have missing values from final models will still lead to
unbiased estimators (Allison 2001).21

21 In evaluating this approach, we compared case information for suspects whose crimes were included in the final
models with those whose crimes dropped out due to missingness on at least one variable, and found no significant
differences in offense type, age of the case, number of suspects reported to the forensic lab, number of victims, whether
the offense involved a firearm, number of different types of preconviction forensic tests performed, and number of
preconviction forensic tests that included the convicted offender.

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Measures
In this section, we describe the measures created from data collected for this project, which are
divided into five categories: post-conviction DNA testing variables, preconviction forensic testing
variables, case characteristics, suspect and victim demographics, and characteristics of the Virginia
counties in which the convictions occurred.
Post-Conviction DNA Testing Variables
These variables document the results of the post-conviction DNA testing and were derived by UI
researchers from the certificates of analysis that DFS completed after reviewing testing results from
the private laboratory. The variables included herein are as follows:
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Red case (versus Green): As described in the Data section, DFS designated Red cases as those
for which DNA testing results included exculpatory evidence in favor of at least one
convicted offenders . UI researchers coded each conviction stemming from these cases as
either 1=Red or 0=Green for this measure.
DNA testing yielded a DNA profile: This measure was coded as 1=yes if post-conviction DNA
testing resulted in at least one DNA profile, which was a necessary but not sufficient
condition for making conclusions about a convicted offender’s probable involvement in an
offense. All determinate results depended on development of a DNA profile, but many
indeterminate results also had a profile developed. If no profile of value was developed, this
measure was coded as 0=no.
Textile item developed DNA profile: This measure was one of five general categories designated
by UI to capture most of the types of physical evidence that were analyzed. This specific
variable indicates whether a DNA profile was developed from a textile item, which included
the suspect or victim’s clothing (excluding panties, which were coded separately below),
bedspreads, furniture fabric, and stains from different textile materials.
Vaginal swab developed DNA profile: This measure indicates that a DNA profile was developed
from vaginal and/or thigh/vulva swabs, which were typically collected as part of the victim
physical evidence recovery kit (PERK), but which were sometimes collected from victims
separately from a full PERK.
Anal swab developed DNA profile: This measure includes DNA profiles developed from anal
swabs that were collected from either the victim or suspect, including those obtained from a
PERK.
Oral swab developed DNA profile: This measure includes oral swabs collected from either the
victim or suspect, including those obtained from a PERK.
Panties developed DNA profile: This item is coded separately from textiles above and specifically
refers to DNA profiles developed from panties or underwear collected from the crime
scene, including those obtained from a victim PERK, as well as those items collected from
the victim or suspect at a later date.
Reference sample developed DNA profile: Reference samples were collected from the victim
and/or suspect separately from a PERK and were used to develop a reference profile (an
“alternate known” profile) for either the victim or the suspect.

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Preconviction Forensic Testing Variables
These variables were designed to capture any information about the forensic tests that were
conducted to aid the original investigation and whether results of these tests implicated the
convicted offender in his/her original case. The variables were split into two categories: items
collected (the amount and types of forensic evidence collected at the crime scene22 and from the
suspects/victims for comparison purposes23) and forensic tests conducted. To summarize this
information for final analyses, UI created the following variables:


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




Number of different types of forensic tests done: This measure produces a count of the number of
different types of forensic tests that were done (not the total number of tests that were
done—e.g., if multiple microscopic hair comparisons were done, this would only count as
one type of forensic test); values can range from 0 to 6, based on the test types described
below.
Number of different types of forensic tests done that included convicted offender: This measure produces a
count of the number of different types of forensic tests that created a link to the suspect.
For example, if a suspect’s fingerprints matched24 those found at the scene, and his ABO
blood type was included in that found at the scene, this variable would equate to two
different types of matching tests.
Percent of different types of forensic tests done that included convicted offender: This measure is derived
from the previous two variables and is calculated as the number of forensic test types that
included the suspect divided by the number of tests done.
Strength of forensic tests that included a convicted offender: This measure was created to rank the
strength of suspect inclusion based on forensic testing. If no tests included the convicted
offender, this measure was coded as 0. Otherwise, the measure represents the average score
across values assigned as follows, from strongest to weakest type of inclusionary forensic
evidence: fingerprint comparison (=3), microscopic hair comparison (=3), ballistics analysis
(=3), ABO blood group typing (=1), enzyme typing (=1), and racial origin of hair analysis
(=1). The average score could have mathematically ranged from 0 to 3 but in the data ranged
from 0 to 1.75.
Fingerprint comparison done in case: This variable measures whether fingerprints collected at the
scene were compared to latent prints obtained from a suspect or victim.
Fingerprint comparison included convicted offender: If a fingerprint comparison matched latent prints
from a convicted offender, this variable is coded as 1=yes; otherwise 0=no.
Microscopic hair comparison done in case: This variable measures whether a microscopic hair
comparison, a more sophisticated test than the racial origin of hair, was done in the case.
Microscopic hair comparison included convicted offender: If a microscopic hair comparison was done
and included the convicted person’s hair, this variable is coded as 1=yes; otherwise 0=no.
Ballistics analysis done in case: This measures whether firearms or bullets were analyzed and/or
compared to a weapon obtained from the person convicted.25

This includes all questioned evidence, including intimate swabs from sexual assault forensic exams.
This includes all known evidence (i.e., reference samples), collected to be compared with collected questioned
evidence.
24 The term “match” as it is used in this report indicates any result where the convicted offender cannot be eliminated as
the source of physical evidence.
25 This does not include reconstruction through trajectory analysis or distance determination analysis.
22
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

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Ballistics analysis included convicted offender: If a ballistics analysis on firearms or bullets from the
crime scene was conducted and linked to a weapon belonging to the convicted offender, this
variable is coded as 1=yes; and otherwise 0=no.
ABO blood group typing done in case: This variable measures whether ABO blood group typing
was conducted to determine the blood type of biological material left at the scene.
ABO blood group typing included convicted offender: If ABO blood group typing was conducted on
questioned evidence from the crime scene and the blood type included that of the person
convicted, this variable is coded as 1=yes; and otherwise 0=no.
Enzyme typing done in case: This variable measures whether testing was done to determine the
type of blood enzymes left at the crime scene This includes all non-ABO typing systems
including other antigen markers, protein markers (Hb, Hp), and actual enzyme markers (such
as PGM, ESD, EAP). In the pre-DNA era, the more types used to link questioned and
known items, the higher the likelihood that they came from the same source.
Enzyme typing included convicted offender: Coded as 1=yes if enzyme typing was done and
included the convicted offender’s blood enzyme type; 0=no otherwise.
Racial origin of hair analysis done in case: This variable indicates whether hair collected at the
crime scene or from the victim/suspect was analyzed (subjectively) to place it into one of
three anthropomorphic racial categories.
Racial origin of hair included convicted offenders: This variable indicates whether racial origin of hair
analysis, as described above, implicated the person convicted (1=yes; 0=no).

Case Characteristics
Information about characteristics of the convicted offender’s criminal case and conviction was
recorded in the following measures, which were coded as 1=yes or 0=no, unless otherwise stated:

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Murder is most serious offense
Sexual assault is most serious offense
Firearm was involved in the crime: This was assumed to be “no” unless firearms or ballistics
evidence was specifically mentioned in the crime description or lab report.
Length of case in months: This measured the time from offense to conviction. If offense date
was missing, then the date of forensic evidence submission was used, and if conviction date
was missing, then sentencing date was used.
Age of case in years (time from offense to Jan. 1, 2012)
Location of offense: Victim’s home/apartment
Location of offense: Indoors (inside a home, apartment, or building)
Location of offense: Vehicle (either the convicted offender’s or victim’s)
Location of offense: Private location (no public access): This particularly included the victim’s home
or vehicle, or the convicted offender’s home or vehicle.
Person convicted was stranger (not known prior to day of crime)
Person convicted was relative or (ex)intimate partner of victim(s)
Number of suspects ever reported to forensic lab (regardless of conviction): This measured the number of
suspects reported by police to DFS in the 1970s/80s at the time of original evidence
submissions.
Number of suspects convicted for this crime
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Percent of known suspects who were not convicted for this crime
Number of victims

Convicted Offender/Victim Demographics
Basic demographic information about the convicted offender and victim (e.g., age, gender, race) was
also recorded in the DFS files. We used this information to create a large number of variables, many
of them interactions of convicted offender/victim demographics, which we tested as potential
predictors of exculpatory DNA testing results (they were also tested in models predicting
determinate testing results).

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Convicted offender age
Convicted offender under 18
Convicted offender gender is male
Convicted offender race is black/African-American
Convicted offender race is white/Caucasian
Average victim age
Oldest victim age
Youngest victim age
Any victim under 18
Any victim 65 or older
Any female victim(s)
All female victim(s)
All female and/or juvenile (<18) victim(s)
All juvenile (<18) victim(s)
All female and/or juvenile (<18) and/or elderly (65+) victim(s)
Male convicted offender, all female victim(s)
Male convicted offender, all female and/or juvenile (<18) victim(s)
Male convicted offender, all female and/or juvenile (<18) and/or elderly (65+) victim(s)
Convicted offender is black/African-American male stranger to victim(s)
All victims are black/African-American
Any victim is black/African-American
All victims are white/Caucasian
Any victim is white/Caucasian
Any victim is white/Caucasian female
Black male convicted offender, any white female victim
Black convicted offender, any white victim
Convicted offender and at least one victim are different races

Conviction County Characteristics (Virginia)
Characteristics of the county (or independent city) in which convictions took place were recorded
based on 1970s/80s information derived from the VA County Statistics File. Notably, the data set
includes convictions from 94 (69 percent) of the 137 counties and independent cities in VA during
that time. The county variables can be grouped into the following four categories:
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1. Crime-related variables, which include the number of offenses, violent crimes, murders, sexual
assaults, aggravated assaults, burglaries, property crimes, motor vehicle thefts, and larceny
thefts known to police per 1,000 persons; and the number of police officers per 1,000
persons.
2. Socioeconomic variables, which include the percentage of persons 25 and older with no high
school diploma; percentage of persons 18 and older who did not vote in presidential
election; percentage of female-headed households with children; percentage of renteroccupied housing units; percentage of vacant housing units; percent unemployed persons;
median household income; per capita personal income; percentage living below poverty
level; percentage black/African-American living below poverty level; and percentage
receiving Aid to Families with Dependent Children.
3. Demographic variables, which include the number of persons per square mile; percentage
African American/black; percentage Hispanic/Spanish-origin; percentage unmarried males
15 and older; percentage youth; percentage persons living in different house five years ago;
and percentage rural population.
4. Local government variables, which include local government revenue per 1,000 persons; local
government expenditure on police protection per 1,000 persons; and percentage of local
government revenue spent on police protection.
Additionally, the following variables were used to develop an economic deprivation scale
(standardized, alpha=.796): lack of high school diploma, unemployed adults, percentage living below
the federal poverty level, and percentage on public assistance.

Methodology
Our methodology sought to address the two primary objectives of this evaluation. First, using the
data collected from the DFS forensic files, we determined whether the results of Virginia’s DNA
testing would support exoneration of a convicted defender, inculpate the defendant, or be
insufficient to change the outcome of the case (acknowledging that the nonforensic facts of the case
might affect final classification). Second, we used the same data to identify associations between case
characteristics and the likelihood that DNA testing would produce determinate results and support
exoneration of a convicted defendant. This section discusses the analytic plan that we used to
address both objectives.
The analytic plan was developed iteratively. First, we calculated univariate analyses and
reported descriptive statistics. These statistics include means and proportions (percentages) of the
entire sample and means and proportions of each of the four groups (the one indeterminate group
and the three determinate groups: inculpatory, exculpatory but insufficient for exoneration, and
exculpatory and supporting exoneration). We also evaluated the significance of differences across all
five groups based on the F-statistic. Next, we estimated a series of logistic regressions to compare
each group to the convictions with indeterminate results and to the convictions with inculpatory
results, across all means and proportions, tested one at a time.
From these regressions we selected candidate variables for the final predictive models: a
multivariable logit predicting determinate DNA testing results, and a multivariable logit predicting
exculpatory evidence, given determinate results. Our selection of candidate variables included
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significant predictors of each outcome as well as variables that were theoretically related to
outcomes. Next, we estimated a correlation matrix calculating covariance among the candidate
independent variables.26 When candidate independent variables were highly correlated (r>0.5), we
selected the variable with the strongest theoretical relationship to the dependent variable, or the
independent variable most highly correlated with the dependent variable and deleted the collinear
variable(s). We then estimated each final model in a series of steps, progressively adding independent
variables in blocks: first, preconviction forensic testing variables, then case characteristics, convicted
offender/victim demographics, and county characteristics. Candidate variables that remained
significant in at least one multivariate model or were included as theoretically relevant controls were
kept in the final model.
Dropping Nonsexual Assault Homicide Convictions
Once the preliminary analyses comparing convictions with determinate results to those with
indeterminate results were complete, it became apparent that few nonsexual assaults (only 8 percent)
had determinate outcomes. Thus, we chose not to model correlates of determinate outcomes for
nonsexual assault homicides. Unless otherwise noted, the analysis that follows considers only
convictions for homicide with a sexual assault and sexual assault only.
Table 4. Outcome of DNA Testing Results by Sexual Assault Status
Sexual Assault?
Outcome
No
Yes
Count
270
195
Indeterminate
% of Total
(38%)
(27%)
Count
7
187
Inculpatory
% of Total
(1%)
(26%)
Count
11
7
Exculpatory but insufficient
% of Total
(2%)
(1%)
Count
5
33
Exculpatory supporting exoneration
% of Total
(1%)
(5%)
42228
Count
29327
Total
% of Total
(41%)
(59%)

Total
465
(65%)
194
(27%)
18
(3%)
38
(5%)
715
(100%)

Logistic Regressions
Next, we specified three sets of multivariable logistic regressions each of which was designed to
identify covariation between case attributes and DNA testing outcomes in homicides with a sexual
assault and in sexual assaults:


The first set of regressions estimates the association between case characteristics (including
preconviction forensic testing, convicted offender/victim demographics, and county
attributes) and whether the DNA testing yielded a determinate outcome.

Pearson’s correlation coefficients are not reported here, but are available from the authors upon request.
Nonsexual assault homicides.
28 Includes 47 homicides where a sexual assault occurred and 375 nonhomicide sexual assaults.
26
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

The second set of regressions, run on convictions with determinate outcomes only, estimates
the association between the same such attributes and whether the evidence was potentially
exculpatory,29 as opposed to inculpatory.



The third set of regressions, run on convictions with determinate outcomes only, estimates
the association between the same attributes and whether the evidence was exculpatory and
supported exoneration, as opposed to inculpatory.

Each of the regressions takes the general form of:
Log (Y/1-Y) = α +βFORENSICX + βCASEX + βDEMOX + βCOUNTYX + ε

(1)

where the log of the odds of each of the three dependent variables is regressed (iteratively) on four
blocks of independent variables (preconviction forensic testing variables, case characteristics,
convicted offender and victim demographics, and attributes of the county at the time of the
offense). The final tables report the results of all four and note which model fits the data the best.
Multinomial/Sequential Logistic Regression/Propensity Score Analysis
We considered several alternative model specifications but ultimately chose the more
straightforward models described above. One alternative approach would be to consider each of the
four outcomes simultaneously using a multinomial regression, which is appropriate for categorical
dependent variables. However, the four categories described here are not different levels of the same
variable but rather different concepts. Since inculpatory testing results have a single value but
exculpatory testing results have three possible values (where two are subsets of the third), it is more
conceptually appropriate to consider separately whether the evidence was determinate and whether
it was exculpatory.
Having made that decision, we considered whether to specify a sequential logistic regression
that would predict associations between both stages of case processing. That approach appears
appropriate when simply modeling whether evidence was determinate and whether it was
exculpatory. However, while inculpatory and exculpatory test results are conceptually similar, the
more interesting analysis, comparing probable exonerations to convictions with inculpatory
outcomes, is quite different. Thus, rather than specifying different models for each of the dependent
variables, we chose to use one consistent approach for ease of interpretation.
We note that the first of the three models described above tests for predictors of a
determinate versus indeterminate outcome. These results could be used to generate a prediction of
the likelihood of obtaining a determinate result, which could then be used to reweight the sample to
resemble all convictions. This propensity score weighting approach requires that the first stage
model contain predictors that are associated with a determinate/indeterminate finding, but are not
related to the ultimate DNA testing outcome. However, we were unable to identify any variables
that could achieve that objective. Given that the propensity score weight would be used effectively
to generate a prediction about missing DNA testing outcomes, this propensity score model would
have to be extraordinarily convincing. While such a model might have been plausibly specified if all
data from the courthouses had been collected, in the absence of those data a convincing model
29

This includes all exculpatory results: exculpatory but insufficient and exculpatory but supports exoneration.

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could not be specified. That said, in the final model predicting exculpatory findings we include the
independent variables from the model predicting determinate outcomes as statistical controls.
Clustering
In our sample, because there are 715 convicted suspects in 634 criminal cases in 94 counties, we
were concerned about the potential effects of clustering on our results. That is, because the county is
an important unit of analysis with respect to law enforcement policymaking and because county
courthouses were the venue for case disposition, we could potentially misinterpret differences in
outcome as being due to case attributes when the real causal mechanism is between-county
differences. However, in our sample we have cases from 28 counties in which there was only a single
criminal conviction. Given the distribution of the data, multilevel models would fail to converge,
and models that account for clustered standard errors require at least two observations per cluster.
As an exploratory approach, we deleted those 28 observations and repeated a select number of
logistic regressions specifying clustered standard errors; however, we observed no consistently
substantive change in outcomes and thus report only the logistic regressions that did not control for
clustering.

Results
This section describes the prevalence and correlates of inculpatory and exculpatory DNA evidence
in 634 criminal cases from Virginia between 1973 and 1987 that resulted in 715 convictions for
which the most serious crime was murder (48 percent) or sexual assault (52 percent).
First, we describe how many convictions had retained physical evidence that yielded
determinate DNA testing results (i.e., post-conviction testing yielded enough information to draw a
conclusion about whether the convicted offender was the source of DNA developed from old
evidence) and how many yielded indeterminate results.30 This analysis is conducted for all 715
convictions.
Then, we separate convictions into those for sexual assaults and nonsexual assaults (where
there were few determinate outcomes), and focus on the subset of 422 sexual assault convictions. Of
these sexual assault convictions, 11 percent had murder as the most serious charge and 89 percent
had sexual assault as the most serious charge. We compare convictions for sexual assault and
indeterminate DNA testing outcomes to those for which testing yielded a determinate outcome
(either inculpatory or exculpatory evidence) and use results from those comparisons to iteratively
estimate a final predictive model of determinate DNA testing results in sexual assault convictions.
We then use these final predictors as statistical controls in the subsequent stage. In this subsequent
stage, we first conduct bivariate comparisons of convictions for sexual assault and exculpatory DNA
evidence to those whose DNA evidence implicates the convicted suspect (inculpatory outcomes).
Next, we use information from these comparisons to iteratively estimate a final predictive model of
exculpatory DNA testing results in sexual assault convictions, while controlling for factors related to
determinacy of such results. We then repeat that analysis comparing only convictions with
exculpatory outcomes that are supportive of exoneration to those that are inculpatory and drop
those exculpatory outcomes that do not support exoneration. Throughout this section, we examine

30

The determinacy of DNA testing results relates to specific convicted persons rather than to criminal cases.

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as possible predictors a number of crime, offender, victim, and county characteristics, as well as the
forensic testing performed by DFS prior to the original conviction.
What proportion of convictions had determinate DNA testing results?
Thirty-five percent (n=250) of the 715 convictions for which physical evidence was examined
yielded determinate DNA testing results, as shown in Table 5.31
Table 5. Outcome of All DNA Testing Results

Outcome
No results; additional technology needed
Need convicted offender reference sample
Need victim reference sample
No results of value; DNA profile matches
victim only
Unknown DNA profile OR other DNA
profile present
Need convicted offender and victim
reference samples

Indeterminate
235
70
35

-

-

-

-

14

5

54

(2%)

(1%)

(8%)

-

-

20

(3%)
-

(3%)
-

4

-

(1%)
57

-

-

-

Convicted offender’s DNA profile and
NO other DNA profile present

-

Unknown DNA profile OR other DNA
profile present; convicted offender
eliminated

-

-

57
(8%)

55

-

-

(8%)
39
100

-

-

-

39
(6%)

-

-

-

33

33

(5%)

(5%)

-

48

(14%)
-

55
(8%)

(6%)

48

4
(1%)

(8%)

Convicted offender’s DNA profile and
other DNA profile present

70
(10%)

(5%)
20

Total32
235
(33%)

(10%)

-

Total

Exculpatory
supporting
exoneration
-

(33%)

DNA profile matches convicted offender
reference sample; victim reference sample
not present

No results of value; only DNA profile
developed from reference sample

Inculpatory
-

Exculpatory
but
insufficient
-

100
(14%)

-

(7%)

(7%)

465

194

18

38

715

(65%)

(27%)

(3%)

(5%)

(100%)

Most determinate results are inculpatory (194 of 250 convictions with determinate results, or 78
percent) and are determined to be inculpatory because the profile developed from questioned
evidence included—

31
32

The outcomes shown in Table 5 repeat the outcomes described in figure 2.
Percentages may not sum exactly due to rounding error.

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 the convicted offender alone (100 out of 250 convictions with determinate results; 40
percent of all convictions with determinate results) when a victim reference was available;
 the convicted offender alone (22 percent of convictions with determinate results) when a
victim reference was not available; or
 the convicted offender and another unknown source (16 percent of convictions with
determinate results).
In the remaining 22 percent of convictions with determinate results, the convicted offender was
eliminated as the source of the DNA. However, this alone is not equivalent to a wrongful conviction
or exoneration, as is discussed further below. In 38 convictions (15 percent of convictions with
determinate results), all of the available evidence supports exoneration.33 Those include—


Thirty-three convictions (13 percent of convictions with determinate results) where the
convicted offender was eliminated because an unknown DNA profile was generated that did
not match the convicted offender’s reference standard, and/or there was a match to a
known person who was not the convicted offender or the victim;34



Five convictions (2 percent of convictions with determinate results) where the convicted
offender was eliminated because a DNA profile was generated in a sexual assault with a
male contributor (but no victim standard) who was not the convicted offender.

However, in an additional 18 convictions (7 percent of convictions with determinate results), the
evidence was not sufficient to support exoneration without additional probative evidence. Those
convictions include—


Four convictions (2 percent of convictions with determinate results) where the convicted
offender was eliminated because an unknown DNA profile was generated that did not
match the convicted offender’s reference standard, or there was a match to a known person
who was not the convicted offender or the victim. However, in these convictions that
elimination was not probative, and thus there is insufficient evidence from that finding alone
to support exoneration. This includes convictions where, for example, the questioned
evidence identified a known person who had provided an elimination sample and was
known to have legitimate reason to be at the crime scene. Thus, the convicted offender’s
elimination in these cases was not sufficient to support exoneration.



Fourteen convictions (6 percent of convictions with determinate results) where the
convicted offender was eliminated as the source of a DNA profile. For example, a convicted
offender was eliminated as the source of a DNA profile, but the gender of the actual source
could not be determined. Thus, without a victim standard, it cannot be determined whether
the elimination was probative, and thus there is insufficient evidence from the elimination
alone to support exoneration.

All of the information available to the research team supported exoneration. There may be other evidence that the
research team did not have access to that does not support exoneration.
34 The DNA match to a known offender is not necessarily a match to the “real” perpetrator, as it may be a match to
elimination samples taken from a family member or someone else with a legitimate reason to be present at the crime
scene, even if this association was made through a database hit.
33

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With regard to the convictions with indeterminate DNA testing results (n=465), reasons for this
indeterminacy were varied. DNA testing produced no results for 235 convictions. In other
convictions, a profile was developed but a) there was no convicted offender reference sample35 to
which to compare the questioned (crime scene) evidence (n=70); b) there was no victim reference
sample (n=35)36; or c) both a convicted offender and victim reference sample were missing (n=57).
In some cases, the questioned evidence matched to only the victim (n=20). In 10 percent of
convictions with indeterminate results (7 percent of all convictions), a reference sample existed, but
no questioned evidence developed a profile that could be compared to a reference sample.
What factors distinguish convictions with determinate and indeterminate DNA testing
results?
As noted in the Methodology section, the primary factor distinguishing convictions with determinate
and indeterminate DNA testing results was whether or not a sexual assault had occurred. Very few
nonsexual assault convictions (only 8 percent) had determinate DNA testing outcomes. On the
other hand, 54 percent of sexual assault convictions resulted in a determinate outcome after postconviction DNA testing was performed. Therefore, unless otherwise noted, the analysis that
follows considers only convictions that involved a sexual assault, including homicides with a
sexual assault and rape cases.
In the next sections, we identify factors that distinguished determinate sexual assault
convictions from indeterminate sexual assault convictions, on a bivariate basis, with regard to the
following types of variables:






post-conviction DNA testing (Table 6),
preconviction forensic testing (Table 7),
case characteristics (Table 8),
convicted offender/victim demographics (Table 9), and
conviction county characteristics (Table 10).

Table 6 shows that for all sexual assault convictions, 54 percent resulted in a determinate
outcome after post-conviction DNA testing was performed. In all of these cases, lab analysts
developed DNA profiles from at least one piece of questioned evidence and were able to make
meaningful comparisons to determine if the person originally convicted could be eliminated (or not)
as the DNA contributor. Of the 195 (46 percent) indeterminate sexual assault convictions, 73
percent also had at least one profile developed from old evidence yet lacked sufficiently relevant
profiles for determinate comparisons. Thus, even when physical evidence is preserved and DNA
testing on it produces a profile, it is not always sufficient to draw conclusions from those profiles
that aid investigations, either pre or post-conviction. For example, a convicted offender or victim
reference sample may still be needed to compare DNA found on crime scene evidence, or only

The convicted offender reference sample could come from the original case file or be obtained for purposes of postconviction DNA testing—for samples that were obtained, the convicted person either voluntarily submitted a sample or
the sample was obtained from the Virginia DNA databank.
36 In 55 cases there was no reference sample. In 20 of the cases, the case was a sexual assault where the victim’s gender
was known and thus she could be excluded as a possible contributor of a male DNA profile. In 35 cases the case was
not a sexual assault, or the victim and offender were of the same gender or the gender of the profile was unknown and
thus the results are indeterminate.
35

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POST-CONVICTION DNA TESTING & WRONGFUL CONVICTION

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reference profiles are developed.
Table 6. Bivariate Comparison of Determinate and Indeterminate Sexual Assault
Convictions: Post-Conviction DNA Testing
Proportion / Mean

Post-Conviction DNA Testing
Variables
DNA testing yielded a DNA
profile
Textile item developed DNA
profile
Vaginal swab developed DNA
profile
Anal swab developed DNA profile
Oral swab developed DNA profile
Panties item developed DNA
profile
Reference sample (from old case
file) developed DNA profile

Indeterminate
(n=195)
46%

Determinate
(n=227)
54%

Total
(n=422)
100%

% missing

Significance of
Difference

73%

100%

87%

0%

N/A

22%

48%

36%

0%

.000

29%

41%

36%

0%

.012

3%

6%

5%

0%

.144

10%

33%

23%

0%

.000

18%

45%

33%

0%

.000

4%

12%

9%

0%

.017

By definition, determinate results were obtained when at least one profile from questioned
evidence could be compared to convicted offender and victim reference profiles.37 Of the item types
listed in Table 6, reference profiles could have been obtained from known reference samples or
from any female profile developed from an intimate swab (oral, vaginal, anal). Reference profiles
from the latter category were usually referred to as “alternate known reference profiles” because
while they did not come from a designated reference swab, it is very likely that the victim was the
true source of that profile. With the exception of anal swabs, profiles developed from all of these
sources are associated with determinate outcomes. Intimate swabs, as well as any nonreference
sample source (textile and panties), may have also develop profiles foreign to the victim and
comparable to convicted offender or other reference profiles. Thus, it is not surprising that sources
of both reference and questioned profiles are associated with determinate results.
We can observe the relative usefulness of profiles from these evidence types by comparing
the differences between the averages in each outcome. The yield of each evidence type—that is, the
rate at which evidence items produce profiles and the rate that those profiles are used to make
meaningful comparisons, is not quantified in this data set but is reflected in the differences of the
averages in Table 6. Profiles from textiles, panties, and vaginal swabs were the most valuable,
followed closely by profiles from oral swabs. Actual reference items from the old evidence were
moderately useful in making determinate conclusions. Profiles from anal swabs were the least
valuable in making any determination and the only profile source that was not associated with
determinate outcomes.
A victim reference profile is not necessary if the gender of the questioned profile contributor is known and it is
different from the victim’s gender. A female victim can be eliminated as the source of a questioned profile from a male
contributor.

37

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As shown in Table 7, there were a number of bivariate differences between sexual assault
convictions with determinate and indeterminate DNA testing results, with regard to attributes of the
original forensic testing performed. For convictions with determinate results, more types of forensic
tests had been performed prior to conviction, more types of these tests had established a connection
with the person convicted (i.e., the convicted offender could not be eliminated as the source of
evidence), and these connections were relatively stronger for convictions with determinate results
than for convictions with indeterminate results (based on a scaling of forensic testing that ranked,
for example, microscopic hair analysis as strong and racial origin of hair analysis as weak). Of the
variables that described specific forensic tests, determinate DNA testing outcomes were more likely
in sexual assault convictions where the convicted offender was not eliminated as the source of
biological evidence through ABO typing or through racial hair characterization.38
Table 7. Bivariate Comparison of Determinate and Indeterminate Sexual Assault Cases:
Preconviction Forensic Testing
Proportion / Mean
Indeterminate
(n=195)

Determinate
(n=227)

Total
(n=422)

%
missing

Significance
of Difference

1.69

1.83

1.76

0%

.072

.72

.93

.83

0%

.007

41%

50%

46%

0%

.028

.20

.24

.22

0%

.064

12%

10%

11%

0%

.585

1%

1%

1%

0%

.657

3%

2%

2%

0%

.808

1%

0.4%

0.5%

0%

.914

7%

6%

6%

0%

.835

Ballistics analysis included convicted offender

3%

0.4%

1%

0%

.105

ABO blood group typing done in case

97%

97%

97%

0%

.789

37%

49%

44%

0%

.011

12%

15%

14%

0%

.359

Preconviction Forensic Testing Variables
Number of different types of forensic tests done
Number of different types of forensic tests done
that included the convicted offender
Percentage of different types of forensic tests
that included the convicted offender
Strength of forensic tests that included the
convicted offender (0=none, 1=weak, 3=strong)
Fingerprint comparison done in case
Fingerprint comparison included the convicted
offender
Microscopic hair comparison done in case
Microscopic hair comparison included convicted
offender
Ballistics analysis done in case

ABO blood group typing included convicted
offender
Enzyme typing done in case
Enzyme typing included convicted offender

5%

5%

5%

0%

.912

Racial origin of hair analysis done in case

38%

52%

46%

0%

.007

Racial origin of hair included convicted offender

27%

37%

32%

0%

.030

Racial origin of hair was only forensic test that
included convicted offender

15%

16%

16%

0%

.687

Racial origin of hair uses the gross characteristics of hair to place it in one of three anthropomorphic categories. This
determination is not absolute and is a much less specific hair comparison than that performed by the comparison of
microscopic characteristics (DeForest, Gaensslen, and Lee 1983).
38

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In Table 8, we find several statistically significant case characteristics that were associated
with whether post-conviction DNA testing results were determinate (or not). Crimes that were
somewhat more recently committed (32 instead of 34 years ago), that were committed inside the
victim’s residence, and that involved conviction of a suspect who was a stranger to the victim were
all associated with a higher likelihood of determinate DNA testing findings. Several other case
attributes were not statistically significant, but were highly correlated with a determinate finding,
including a crime committed in a private location, and with more victims. Notably, having an
additional known suspect who was identified but not convicted was neither statistically nor
substantively associated with the likelihood of determinate DNA testing outcomes.
Table 8. Bivariate Comparison of Determinate and Indeterminate Sexual Assault
Convictions: Case Characteristics
Proportion / Mean
Indeterminate

Determinate

Total

(n=195)

(n=227)

(n=422)

%
missing

Significance of
Difference

Case Characteristics
Murder is most serious offense

13%

10%

11%

0%

.310

Rape is most serious offense

87%

90%

89%

0%

.310

7%

6%

6%

0%

.835

7.66

8.41

8.06

23%

.446

33.75

32.38

33.01

0%

.000

32%

49%

41%

27%

.002

57%

63%

60%

27%

.237

24%

20%

22%

27%

.468

63%

71%

67%

27%

.151

83%

92%

88%

24%

.012

6%

3%

4%

25%

.237

1.38

1.47

1.43

0%

.329

1.16

1.20

1.18

0%

.403

7%

8%

8%

0%

.489

1.05

1.10

1.08

0%

.149

Firearm was involved in the crime (assumed
no unless mentioned)
Length of case in months (time from offense
to conviction/sentencing)
Age of case in years (time from offense to Jan.
1, 2012)
Location of offense: Victim’s
home/apartment
Location of offense: Indoors (inside
home/apartment/building)
Location of offense: Vehicle (convicted
offender’s or victim’s)
Location of offense: Private location (no
public access)
Convicted offender was stranger (not known
prior to day of crime)
Convicted offender was relative or
(ex)intimate partner of victim(s)
Number of suspects ever reported to forensic
lab (regardless of conviction)
Number of suspects convicted for this crime
Percentage of known suspects who were not
convicted for this crime
Number of victims

With regard to demographics of the convicted offenders and victims involved, we found few
differences between cases where a determinate finding could be made and cases where it could not
(Table 9). The only significant difference in these convictions was that the convicted offender
tended to be slightly older in convictions with indeterminate results. When the convicted offender
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was black/African American and a stranger to the victim, the conviction was more likely to have a
determinate DNA testing outcome, although this association was not significant and data were
missing in more than a quarter of convictions.
Table 9. Bivariate Comparison of Determinate and Indeterminate Sexual Assault
Convictions: Convicted Offender/Victim Demographics
Proportion / Mean
Indeterminate
(n=195)

Determinate
(n=227)

Total
(n=422)

%
Missing

Significance

25.98
7%
99%

24.62
3%
100%

25.25
5%
100%

7%
6%
5%

.053
.054
.890

56%

61%

59%

6%

.323

43%
25.88

39%
25.55

41%
25.70

6%
11%

.381
.833

Any victim 65 or older
Any female victim(s)

25.91
25.84
30%
4%
95%

25.94
25.20
24%
4%
94%

25.93
25.49
27%
4%
95%

11%
11%
11%
11%
9%

.988
.683
.176
.870
.525

All female victim(s)

94%

92%

93%

9%

.542

All female and/or juvenile (<18) victim(s)

96%

97%

97%

11%

.756

All juvenile (<18) victim(s)

29%

23%

26%

11%

.149

98%

97%

97%

11%

.719

93%

92%

93%

11%

.745

96%

98%

97%

14%

.506

98%

98%

98%

14%

.991

48%

55%

52%

28%

.211

Convicted Offender/Victim Demographics
Convicted offender age
Convicted offender under 18
Convicted offender gender is male
Convicted offender race is black/African
American
Convicted offender race is white/Caucasian
Average victim age
Oldest victim age
Youngest victim age
Any victim under 18

All female and/or juvenile (<18) and/or
elderly (65+) victim(s)
Male suspect, all female victim(s)
Male suspect, all female and/or juvenile (<18)
victim(s)
Male suspect, all female and/or juvenile (<18)
and/or elderly (65+) victim(s)
Convicted offender is black/African-American
male stranger to victim(s)
All victims are black/African American

26%

28%

27%

9%

.750

Any victim is black/African American

27%

28%

27%

9%

.949

All victims are white/Caucasian

73%

72%

72%

9%

.867

Any victim is white/Caucasian

74%

72%

73%

9%

.750

Any victim is white/Caucasian female

71%

69%

70%

9%

.618

30%

33%

32%

12%

.567

32%

34%

33%

12%

.627

33%

36%

35%

12%

.534

Black male convicted offender, any white
female victim
Black convicted offender, any white victim
Convicted offender and at least one victim are
different races

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Table 10 compares sexual assault convictions with determinate and indeterminate DNA
testing results across a number of characteristics regarding the counties in which the convictions
occurred. Few statistically significant associations emerged from this comparison. The counties with
convictions that had determinate outcomes were slightly poorer than those with indeterminate
outcomes, as shown by marginally significant differences (p<0.10) on an economic deprivation scale
and with regard to the number of persons living in poverty, household and per capita income, and
unemployment. We found no associations between determinate outcomes and the county-level
indicators.
Table 10. Bivariate Comparison of Determinate and Indeterminate Sexual Assault
Convictions: Conviction County Characteristics
Proportion / Mean
Indeterminate

Determinate

Total

(n=195)

(n=227)

(n=422)

% missing

Significance
of
Difference

52.78

52.81

52.80

0%

.990

5.08

5.34

5.22

0%

.454

.52

.53

.53

0%

.600

1.83

1.90

1.87

0%

.227

35%

36%

36%

0%

.190

52%

54%

53%

0%

.077

.72

.70

.71

0%

.399

.04

.03

.04

0%

.431

5%

5%

5%

0%

.749

7%

8%

7%

0%

.147

12%

13%

13%

0%

.233

6%

7%

6%

0%

.212

6%

6%

6%

0%

.095

Median household income (1979)

$17,379

$16,589

$16,954

0%

.061

Per capita personal income (1978)

$8,274

$7,844

$ 8,042

0%

.052

27%

28%

27%

0%

.693

Conviction County Characteristics (Virginia)
Number of offenses known to police per
1,000 persons (1978)
Number of violent crimes (murder, rape,
robbery, aggravated assault) known to police
per 1,000 persons (1981)
Number of murders and rapes known to
police per 1,000 persons (1981)
Number of police officers per 1,000 persons
(1977)
Percentage 25 and older with no high school
diploma (1980)
Percentage 18 and older who did not vote in
presidential election (1980)
Local government revenue per 1,000
persons (1977)
Local government expenditure on police
protection per 1,000 persons (1977)
Percentage local government revenue spent
on police protection (1977)
Percentage female-headed households with
children (1980)
Percentage female-headed households
(1980)
Percentage vacant housing units (1980)
Percentage unemployed persons (1980)

Percentage black/African American (1980)
Percentage Hispanic/Spanish-origin
population (1980)
Percentage youth 15 to 21 (1980)

2%

2%

2%

0%

.210

14%

14%

14%

0%

.321

Percentage living below poverty level (1979)

12%

13%

13%

0%

.107

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POST-CONVICTION DNA TESTING & WRONGFUL CONVICTION
Percentage black/African-American persons
living below poverty level (1979)
Percentage receiving Aid to Families with
Dependent Children (1980)
Economic deprivation scale (standardized,
alpha=.796)

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7%

7%

7%

0%

.269

4%

5%

4%

0%

.231

-.15

.003

-.07

0%

.104

What model predicts whether DNA testing results on a case will lead to determinate or
indeterminate conclusions about conviction?
Based on the significant associations observed in the previous bivariate comparisons, we
estimated a model predicting whether DNA testing results on sexual assault convictions would lead
to determinate or indeterminate conclusions. Table 11 presents the four iterations of this model,
which conclude in the final and fifth iteration that contains only the predictors found to be
significant in at least one prior iteration. Table 12 provides details on the final predictive model’s
results. As shown in Table 11, the first model included only preconviction forensic testing variables,
the second added case characteristics, the third added convicted offender/victim demographics, and
the fourth added county conviction characteristics.
Table 11. Multivariate Logit Model Predicting Determinate DNA Testing Results
Model N
Akaike information criterion (AIC) correcteda
Nagelkerke R-square
Preconviction Forensic Testing Variables
Number of different types of forensic tests done that
included convicted offender
ABO blood group typing included convicted
offender
Racial origin of hair analysis done in case
Case Characteristics
Age of case in years (time from offense to Jan. 1,
2012)
Location of offense: Victim’s home/apartmentb
Convicted offender was stranger (not known prior to
day of crime)b
Convicted Offender/Victim Demographics
Convicted offender age

(1)
422
574.44
0.044

(2)
309
405.12
0.132

(3)
294
382.69
0.155

(4)
294
385.11
0.162

Final Model
294
380.73
0.154

Beta

Beta

Beta

Beta

Beta

-0.181

-0.066

-0.121

-0.126

0.719*

0.613

0.753†

0.727

0.613*

0.652*

0.410

0.476

0.469

0.390

-0.10**

-0.115**

-0.101*

-0.116**

0.711**

0.637*

0.641*

0.633*

0.684†

0.564

0.498

0.584

-0.034†

-0.037†

-0.034†

Conviction County Characteristics (Virginia)
Percentage 18 and older who did not vote in
2.216
presidential election (1980)
Per capita personal income (1978)
0.000
Constant
-0.302†
2.386†
3.698*
2.439
3.706*
a
Notes: K. P. Burnham and D. R. Anderson, 2002, Model Selection and Multimodel Inference: A Practical Information-Theoretic
Approach, 2nd ed. Springer-Verlag.
b Missing values for 24 percent to 27 percent of convictions. Significance levels defined as † p<.10, * p<.05, ** p<.01,
*** p<.001.

Although we conducted and present results from these analyses in iterative models, it is the
final predictive model (shown in the last column of Table 11 and in Table 12) whose results we
focus on when interpreting what conclusions can be made. All else equal, the most significant
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predictors of whether DNA testing of evidence from a sexual assault conviction (in Virginia in the
1970s/80s) yielded determinate conclusions about wrongful conviction were as follows: in cases
where ABO blood group typing was performed and included the convicted offender, DNA testing
was more likely to lead to determinate results than in cases where this forensic test was not
performed. In addition, sexual assaults that occurred within the victim’s own residence were more
likely to yield conclusive DNA testing results than sexual assaults that occurred elsewhere. Older
cases and those involving older convicted offenders (at the time of the offense) were less likely to
yield conclusive DNA testing results. Notably, despite their significant bivariate associations with
determinate DNA outcomes, variables measuring the number of preconviction forensic tests that
included the convicted offender and county of conviction characteristics were not significant in the
final multivariate model predicting the likelihood of determinate DNA testing results.
Table 12. Final Multivariate Logit Model Predicting Determinate DNA Testing Results
Beta
294
380.73
0.154

SE

Exp(B)

Model N
Akaike information criterion (AIC) correcteda
Nagelkerke R-square
ABO blood group typing included convicted offender

0.613*

0.254

1.846

Racial origin of hair analysis done in case
Age of case in years (time from offense to Jan. 1, 2012)
Location of offense: Victim’s home/apartmentb
Convicted offender was stranger (not known prior to day of
crime)b

0.390
-0.116**
0.633*

0.251
0.039
0.259

1.477
0.891
1.884

0.584

0.392

1.794

Convicted offender age

-0.034†

0.019

0.966

Constant
3.706*
1.444
a
Notes: K. P. Burnham and D. R. Anderson, 2002, Model Selection and Multimodel Inference: A Practical Information-Theoretic
Approach, 2nd ed. Springer-Verlag.
b Missing values for 24 percent to 27 percent of convictions. Significance levels defined as † p<.10, * p<.05, ** p<.01,
*** p<.001.

Using results from the final model presented in Table 12, we calculated the predicted
probability that each sexual assault in the final model would yield determinate DNA testing results.
Based on these calculations, we note the following conclusions: The predicted probability that DNA
testing of a sexual assault conviction in this sample would yield determinate results ranging from .14
to .87, with a mean of .55. Controlling for all other known factors, this predicted probability was—





.65 for convictions where ABO blood group typing included the convicted offender,
compared to .46 for convictions where it did not (difference of .19);
.61 for convictions where racial origin of hair analysis was done in the case, compared to
.50 for convictions where it was not (difference of .11);
.71 for convictions in cases that were 24 to 29 years old, compared to .60 for cases that
were 30 to 34 years old, and .45 for cases that were 35 to 39 years old (difference ranging
from .11 to .26);
.64 for convictions where the offense occurred in the victim’s home, compared to .49 for
convictions where it occurred elsewhere (difference of .15);
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POST-CONVICTION DNA TESTING & WRONGFUL CONVICTION





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.57 for convictions when the convicted offender was a stranger, compared to .39 for
convictions when the convicted offender was known to the victim (however, this
difference was not statistically significant when controlling for other factors in the final
predictive model);
.60 for convictions where the convicted person was 14 to 20 years old, .56 where he was
21 to 29 years old, and .46 where he was 30 years or older (difference ranging from .04
to .14).

From these predicted probabilities, it appears that four factors stand out as the most substantively
meaningful predictors of determinate DNA testing outcomes among sexual assault convictions in
this data set: the age of the case, whether preconviction ABO typing included the convicted
offender, location of the offense, and age of the convicted offender. More recent cases, cases where
ABO typing included the convicted person, offenses that occurred inside the victim’s home, and
younger convicted persons were all associated with significantly and substantially higher probabilities
of determinate post-conviction DNA testing results.
Table 11 describes the results of the final model which includes any predictor found to be
significant (p<0.10) in any prior stage (column 5 of Table 11). All of the predictors are significant in
the same direction as described above, except for stranger crimes, which are positively correlated
with convictions with determinate results, although the relationship is not statistically significant.
Overall, having characterized hair by race increases the odds that there will be a determinate finding
from the new DNA analysis by about 60 percent. Each additional year in age of the case reduces the
odds of a determinate test by about 10 percent. A crime occurring in the victim’s home more than
doubles the odds of a determinate finding, and each additional year in age of the convicted offender
reduces the odds of a determinant finding by about 4 percent.
What factors distinguish inculpatory sexual assault convictions from all convictions with
exculpatory evidence (either currently insufficient or supportive of exoneration)?
Next, we focus on the sexual assault convictions that resulted in determinate DNA testing results
(n=227) and identification of the factors associated with exculpatory evidence, indicative of a
potential wrongful conviction. Toward this end, we begin with bivariate comparisons, similar to
those in the previous section but this time comparing sexual assault convictions with exculpatory
results to convictions with inculpatory results. We again examine factors grouped into the following
categories:






post-conviction DNA testing variables (Table 13),
preconviction forensic testing variables (Table 14),
case characteristics (Table 15),
convicted offender/victim demographics (Table 16), and
county of conviction characteristics (Table 17).

As shown in Table 13, sexual assault convictions with exculpatory DNA testing results were
significantly associated with three post-conviction DNA testing factors: DNA profiles developed
from oral swabs, anal swabs, and reference samples. As noted in previous sections, reference sample
evidence was required for certain determinate conclusions to be reached, so it is not surprising that a
higher number of convictions with exculpatory results (38 percent) than inculpatory results (6
percent) depended on reference sample DNA profiles. Additionally, it was frequently observed
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during UI’s coding of the DFS files that DNA profiles developed from oral swabs were used as
alternate known references for victims and suspects. However, this fact alone does not explain why
oral profile sources were more strongly associated with exculpatory outcomes. There were no
statistically significant differences between inculpatory and exculpatory sexual assault convictions
with regard to other post-conviction DNA testing variables, including whether DNA profiles were
developed from textile items, vaginal swabs, or the victims’ underwear.
Table 13. Bivariate Comparison of Exculpatory and Inculpatory Sexual Assault Convictions:
Post-Conviction DNA Testing Variables	
Proportion / Mean

Post-Conviction DNA Testing Variables
Red case (not Green), designation by DFS

Inculpatory

Exculpatory

Total

(n=187)

(n=40)

(n=227)

Significance of
Difference

6%

95%

22%

.000

DNA testing yielded a DNA profile

100%

100%

100%

N/A

Textile item developed DNA profile

47%

53%

48%

.493

Vaginal swab developed DNA profile

43%

33%

41%

.232

Anal swab developed DNA profile

5%

13%

6%

.077

Oral swab developed DNA profile

23%

83%

33%

.000

Panties item developed DNA profile

44%

50%

45%

.518

Reference sample (from old case file) developed DNA
profile

6%

38%

12%

.000

With regard to the original, preconviction forensic testing variables (Table 14), one attribute
was associated with inculpatory DNA testing results, while four seemingly separate but related
attributes were associated with exculpatory results. Specifically, convictions with inculpatory results
were more likely to have had enzyme typing performed on the original biological evidence (18
percent), compared to those with exculpatory results (5 percent). Enzyme typing, especially when
combined with ABO typing results, increased the specificity of overall forensic serological testing.
With regard to bivariate predictors of exculpatory DNA testing results, the only
preconviction forensic testing variable that was associated with exculpatory DNA results was racial
origin of hair analysis, even when it included the convicted offender, and when it was the only
forensic test that included the convicted offender. Previous publications have warned that
“determinations of racial origin must be approached with a good deal of caution” (DeForest,
Gaensslen, and Lee 1983). For the cases in this study, we cannot know if the conclusions reached
regarding this work were accurate or not.39 Since this type of work links hair to one of three broad
classes, not to a specific individual, it is possible to have correct racial origin determinations in an
actual wrongful conviction.
Notably, none of the other preconviction forensic testing variables was significantly
associated with exculpatory DNA testing results, including whether a fingerprint comparison was
done in the original case and/or included the convicted offender, whether ABO blood group typing
39

This is true for all preconviction forensic testing conducted on the cases in this study.

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was done and/or included the convicted offender, and whether microscopic hair analysis or ballistics
analysis were done (though they rarely were and virtually never included the convicted offender).40
Table 14. Bivariate Comparison of Exculpatory and Inculpatory Sexual Assault Convictions:
Preconviction Forensic Testing Variables
Proportion / Mean
Inculpatory

Exculpatory

Total

(n=187)

(n=40)

(n=227)

Significance of
Difference

1.81

1.93

1.83

.378

.90

1.05

.93

.279

49%

53%

50%

.574

.24

.26

.24

.487

12%

3%

10%

.112

Fingerprint comparison included convicted offender

1%

0%

1%

N/A

Microscopic hair comparison done in case

2%

3%

2%

.888

Microscopic hair comparison included convicted offender

1%

0%

0.4%

N/A

Ballistics analysis done in case

5%

10%

6%

.275

Ballistics analysis included convicted offender

1%

0%

0.4%

N/A

ABO blood group typing done in case

97%

98%

97%

.950

ABO blood group typing included convicted offender

50%

48%

49%

.798

Enzyme typing done in case

18%

5%

15%

.061

Enzyme typing included convicted offender

5%

5%

5%

.960

Racial origin of hair analysis done in case

47%

75%

52%

.002

Racial origin of hair included convicted offender

33%

53%

37%

.023

Racial origin of hair was only forensic test that included
convicted offender

13%

30%

16%

.012

Preconviction Forensic Testing Variables
Number of different types of forensic tests done
Number of different types of forensic tests done that
included convicted offender
Percentage of different types of forensic tests that included
convicted offender
Strength of forensic tests that included convicted offender
(0=none, 1=weak, 3=strong)
Fingerprint comparison done in case

In Table 15, we examine bivariate associations between case characteristics of these sexual
assault convictions and the likelihood of exculpatory DNA testing results. These comparisons
revealed four significant differences and one difference that approached significance. Specifically,
cases that were about two years more recent (31 instead of 33 years old, on average) were more
likely to yield exculpatory DNA testing results. Previously, we also found that more recent cases had
a higher probability of yielding determinate DNA testing results (either exculpatory or inculpatory).
In this specific data set, this seemingly trivial difference in case age may be capturing the distinction
between offenses that occurred in the very late 1970s and those that occurred in 1980 and beyond.
If so, it is possible that evidence from the post-1980 era was less degraded than older cases, thereby
40 Generally, results of ABO blood typing place an item into one of four categories (A, B, AB, or O), which exist at
different frequencies in the population. One may expect that wrongful convictions would be more likely if the convicted
offender was linked through a type held by a large portion of the population, such as A at 45 percent, as opposed to AB
at 4 percent. However, this could not be observed in our analysis.

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increasing the likelihood that such evidence would develop useful profiles, 31 or fewer years later, to
detect possible wrongful convictions.
Three other significant differences between inculpatory and exculpatory sexual assault
convictions have to do with the number of suspects known and convicted for the crime. Not
surprisingly, the more suspects known to police at the time of the original forensic testing, and the
more suspects ultimately convicted for the crime, the more likely it was that post-conviction DNA
testing would yield exculpatory results. The last notable difference, which approached significance at
p=.071, was that when the offense occurred indoors rather than outdoors, post-conviction DNA
testing was more likely to yield an exculpatory (79 percent) than inculpatory (60 percent) result.
With regard to a number of other case characteristics, there were no significant differences
between sexual assault convictions with inculpatory or exculpatory results. These characteristics
included the most serious offense type (murder or rape), firearm involvement, length of the case
from offense to conviction, whether the offense occurred in a vehicle,41 whether the convicted
offender was a stranger versus known acquaintance or intimate/relative, and the number of victims.

Occurring in the victim’s home/apartment or private location, although not achieving significance, was correlated with
occurring indoors, which as noted previously was significantly associated with exculpatory DNA evidence.

41

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Table 15. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and
Inculpatory Results: Case Characteristics
Proportion / Mean
Inculpatory

Exculpatory

Total

(n=187)

(n=40)

(n=227)

Significance of
Difference

Case Characteristics
Murder is most serious offense

9%

13%

10%

.510

Rape is most serious offense

91%

88%

90%

.510

5%

10%

6%

.275

7.96

10.57

8.41

.231

32.70

30.89

32.38

.004

47%

61%

49%

.183

60%

79%

63%

.071

21%

18%

20%

.708

69%

82%

71%

.155

93%

87%

92%

.270

2%

7%

3%

.196

1.37

1.93

1.47

.003

1.15

1.45

1.20

.001

8%

11%

8%

.363

1.12

1.03

1.10

.289

Firearm was involved in the crime (assumed
no unless mentioned)
Length of case in months (time from offense
to conviction/sentencing)
Age of case in years (time from offense to
Jan. 1, 2012)
Location of offense: Victim’s
home/apartment
Location of offense: Indoors (inside
home/apartment/building)
Location of offense: Vehicle (convicted
offender’s or victim’s)
Location of offense: Private location (no
public access)
Convicted offender was stranger (not known
prior to day of crime)
Convicted offender was relative or
(ex)intimate partner of victim(s)
Number of suspects ever reported to forensic
lab (regardless of conviction)
Number of suspects convicted for this crime
Percentage of known suspects who were not
convicted for this crime
Number of victims

In Table 16, we compared a large number of factors measuring convicted offender/victim
demographics in each conviction and found no statistically significant associations between any
factor and the likelihood that DNA testing results would be exculpatory. Notably, our focus in this
section is on all sexual assault convictions with determinate testing outcomes, so virtually all suspects
were male and most victims were female. Still, there was sufficient variation with regard to convicted
offender/victim age and race, and the combinations thereof, to have detected differences had they
existed. Yet, contrary to findings from other studies showing that black/African-American
convicted offenders are overrepresented among exonerees (Garrett 2008) or that the judicial system
is partial to white/Caucasian victims (e.g., Paternoster et al. 2003), we found no evidence of
variation in the likelihood of exculpatory DNA testing results across many tested combinations of
convicted offender/victim race and age compositions.

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Table 16. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and
Inculpatory Results: Convicted offender/Victim Demographics
Proportion / Mean
Inculpatory

Exculpatory

Total

(n=187)

(n=40)

(n=227)

Significance of
Difference

24.37

25.76

24.62

.203

Convicted offender under 18

3%

3%

3%

.939

Convicted offender gender is male

99%

100%

100%

N/A

61%

60%

61%

.885

Convicted Offender/Victim Demographics
Convicted offender age

Convicted offender race is black/African
American
Convicted offender race is white/Caucasian

39%

40%

39%

.885

Average victim age

26.01

23.51

25.55

.345

Oldest victim age

26.33

24.24

25.94

.438

Youngest victim age

25.75

22.79

25.20

.267

Any victim under 18

25%

18%

24%

.373

Any victim 65 or older

5%

3%

4%

.560

Any female victim(s)

94%

93%

94%

.683

All female victim(s)

92%

93%

92%

.901

All female and/or juvenile (<18) victim(s)

98%

95%

97%

.360

All juvenile (<18) victim(s)

23%

18%

23%

.501

98%

95%

97%

.360

92%

93%

92%

.982

98%

95%

98%

.241

98%

95%

98%

.241

All female and/or juvenile (<18) and/or elderly
(65+) victim(s)
Male convicted offender, all female victim(s)
Male convicted offender, all female and/or
juvenile (<18) victim(s)
Male convicted offender, all female and/or
juvenile (<18) and/or elderly (65+) victim(s)
Convicted offender is black/African-American
male stranger to victim(s)
All victims are black/African American

56%

52%

55%

.678

29%

20%

28%

.234

Any victim is black/African American

29%

20%

28%

.234

All victims are white/Caucasian

70%

80%

72%

.209

Any victim is white/Caucasian

70%

80%

72%

.234

Any victim is white/Caucasian female

68%

73%

69%

.552

32%

35%

33%

.747

33%

40%

34%

.399

35%

40%

36%

.581

Black male convicted offender, any white female
victim
Black convicted offender, any white victim
Convicted offender and at least one victim are
different races

Next, we examined the bivariate associations between each of 30 different measures of
county characteristics for the counties in which determinate sexual assault convictions had occurred
and the likelihood of exculpatory DNA testing results. We found only one association that
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approached statistical significance. Specifically, convictions that occurred in counties where local
government spent more on police protection were associated with a somewhat greater likelihood of
exculpatory findings.
However, we also note that, although not achieving statistical significance, all measures of
county-level criminal activity were higher in convictions that resulted in exculpatory DNA findings
than in those with inculpatory findings; and conversely, measures of personal/household income
and the percentage of persons living in rural areas were lower in convictions with exculpatory results
than in those with inculpatory findings. Thus, these bivariate comparisons provide some (albeit
insignificant) support for the fact that poorer urban counties with higher crime rates were more
likely to yield convictions with exculpatory results. Two of these factors (violent crime rate and
median household income) were highly correlated with the percentage of black/African-American
persons living in a county. Not unrelatedly, other measures of county characteristics captured in the
economic deprivation scale indicated that there were higher levels of population density, vacant and
renter-occupied housing, and residential instability (living in different house than five years prior) in
counties that yielded convictions with exculpatory results than in those with inculpatory findings,
though these differences did not achieve statistical significance.

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Table 17. Bivariate Comparison of Sexual Assault Convictions with Exculpatory and
Inculpatory Results: Conviction County Characteristics
Proportion / Mean
Inculpatory

Exculpatory

Total

(n=187)

(n=40)

(n=227)

Significance
of
Difference

52.24

55.47

52.81

.387

5.24

5.81

5.34

.363

.53

.57

.53

.470

1.87

2.13

1.92

.333

2.29

2.54

2.33

.350

57.79

60.34

58.24

.567

14.19

14.61

14.26

.700

39.12

41.08

39.46

.542

1.88

2.00

1.90

.278

36%

38%

36%

.421

53%

54%

54%

.471

.03

.04

.03

.255

4.8%

5.3%

4.9%

.085

8%

8%

8%

.627

Percentage female-headed households (1980)

13%

13%

13%

.252

Percentage vacant housing units (1980)

6%

7%

7%

.227

Percentage unemployed persons (1980)

Conviction County Characteristics (Virginia)
Number of offenses known to police per 1,000 persons (1978)
Number of violent crimes (murder, rape, robbery, aggravated
assault) known to police per 1,000 persons (1981)
Number of murders and rapes known to police per 1,000
persons (1981)
Number of robberies known to police per 1,000 persons
(1979)
Number of aggravated assaults known to police per 1,000
persons (1980)
Number of property crimes (burglary, motor vehicle theft,
larceny-theft) known to police per 1,000 persons (1981)
Number of burglaries known to police per 1,000 persons
(1979)
Number of larceny-thefts known to police per 1,000 persons
(1981)
Number of police officers per 1,000 persons (1977)
Percentage 25 and older with no high school diploma (1980)
Percentage 18 and older who did not vote in presidential
election (1980)
Local government expenditure on police protection per 1,000
persons (1977)
Percentage local government revenue spent on police
protection (1977)
Percentage female-headed households with children (1980)

6%

6%

6%

.504

Median household income (1979)

$16,743

$15,866

$16,589

.226

Per capita personal income (1978)

$7,874

$7,701

$7,844

.642

Percentage of county black/African American (1980)

27%

30%

28%

.327

Percentage Hispanic/Spanish-origin population (1980)

2%

2%

2%

.701

Percentage unmarried males 15 and older (1980)

17%

18%

17%

.254

Percentage youth 15 to 21 (1980)

14%

15%

14%

.124

Percentage rural population (1980)

19%

16%

19%

.521

Percentage living below poverty level (1979)

13%

14%

13%

.459

7%

8%

7%

.295

5%

5%

5%

.325

-.02

.13

.003

.345

Percentage black/African-American persons living below
poverty level (1979)
Percentage receiving Aid to Families with Dependent
Children (1980)
Economic deprivation scale (standardized, alpha=.796)

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What model predicts whether determinate DNA testing results on a conviction will be
exculpatory or inculpatory regarding a convicted offender’s actual innocence?
In this section, we iteratively estimate a model predicting exculpatory DNA testing results based on
the significant bivariate associates identified in the previous section. Toward this end, the first model
includes preconviction forensic testing variables, the second adds case characteristics, the third adds
convicted offender/victim demographics, and the fourth adds county conviction characteristics.
Notably, we also include a number of statistical controls in these multivariate models. Some
controls are included because of their significance in the previously described model predicting
determinate DNA testing results; these controls measure whether ABO blood group typing included
the convicted offender, racial origin of hair analysis was done in the case, age of the case, indoor
offense location,42 number of convicted persons, whether the convicted offender was a stranger, and
the convicted offender’s age. Two other controls are included because of their theoretical relevance
to the model—murder as the most serious offense type (versus rape) and number of victims.
In Table 18, we present the four iterations of the model predicting exculpatory DNA testing
results, along with the fifth iteration (final model), which contains all predictors that were statistically
significant in at least one prior stage plus the control variables. Interpretation of these results focuses
on the final model.

Although technically offense location in the victim’s home/apartment was previously found to be related to
determinate DNA testing results, given its high correlation (r>.5) with indoor locations in general and given the bivariate
relevance of indoor locations to exculpatory cases, we instead included indoor location in the multivariate model
predicting exculpatory DNA testing outcomes.
42

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Table 18. Multivariate Logit Models Predicting Exculpatory DNA Testing Results

Model N
a

Akaike information criterion (AIC) corrected
Nagelkerke R-square

(1)

(2)

(3)

(4)

Final
Model

227

171

162

162

162

202.40

131.32

125.58

127.88

128.10

0.120

0.373

0.401

0.402

0.400

Beta

Beta

Beta

Beta

Beta

Preconviction Forensic Testing
Variables
ABO blood group typing included
convicted offender
Enzyme typing done in case

0.273

0.423

0.479

0.477

0.647

-1.381†

-1.888†

-2.237*

-2.235†

-2.218*

Racial origin of hair analysis done in case

0.998*

0.809

0.633

0.632

0.518

Racial origin of hair was only forensic test
that included convicted offender

0.671

-0.100

-0.427

-0.418

1.461†

1.488†

1.498†

1.424†

-0.196*

-0.219**

-0.220**

-0.221**

1.354*

1.394*

1.396*

1.372*

-1.426†

-1.302

-1.306

-1.293

1.987***

2.082***

2.069***

2.120***

-0.563

-0.556

-0.550

-0.572

0.054

0.054

0.055

Case Characteristics
Murder is most serious offense
Age of case in years (time from offense to
Jan. 1, 2012)
Location of offense: Indoors (inside
home/apartment/building)b
Convicted offender was stranger (not
known prior to day of crime)b
Number of suspects convicted for this
crime
Number of victims
Convicted Offender /Victim
Demographics
Convicted offender age
Conviction County Characteristics
(Virginia)
Percentage local government revenue
spent on police protection (1977)
Constant

2.508
-2.291***

2.410

1.695

1.594

1.615

Notes: a K. P. Burnham and D. R. Anderson, 2002, Model Selection and Multimodel Inference: A Practical InformationTheoretic Approach, 2nd ed. Springer-Verlag.
b Missing values for 24 percent–27 percent of convictions. Significance levels defined as † p<.10, * p<.05, ** p<.01,
*** p<.001.

All else equal, there were five significant predictors of whether determinate DNA testing of
evidence from a sexual assault conviction (in Virginia in the 1970s/80s) yielded exculpatory evidence
indicative of wrongful conviction, in the final multivariate predictive model. Specifically, as shown in
Table 19—


More recent offenses were more likely to have an exculpatory DNA results, although we
note that the difference in the averages was only two years.
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POST-CONVICTION DNA TESTING & WRONGFUL CONVICTION









URBAN INSTITUTE

Sexual assault convictions for which enzyme typing was done were significantly less
likely to yield exculpatory DNA testing results. As noted previously, enzyme typing
increased the specificity of forensic serological tests, especially when combined with
ABO typing results, meaning that stronger conclusions about a convicted offender’s
inclusion as the source of forensic evidence could have been made prior to the original
conviction.
Convictions for both murder and sexual assault were more likely to yield exculpatory
DNA results than were convictions for sexual assault alone. This finding is difficult to
explain, given that greater amounts of physical evidence were likely available in murder
and sexual assault cases than in those involving only sexual assault.
Sexual assault convictions for offenses that occurred indoors, such as inside the victim’s
or convicted offender’s home, were significantly more likely to yield exculpatory DNA
results. Although untestable in the current data set, this relationship may be indicative of
the lack of reliable eyewitness testimony in such cases. The crime descriptions for many
indoor sexual assaults indicated that they frequently occurred at nighttime (in the dark)
and involved only the victim and convicted offender and no other potential witnesses.
The more suspects convicted for a sexual assault, the more likely any individual suspect’s
conviction was to have exculpatory DNA results.

Other variables in the final model had significant bivariate associations with exculpatory DNA
testing results, but did not have significant relationships in the multivariate that controlled for other
factors. These variables included racial origin of hair analysis being done in the case and the single,
county-level indicator: percentage of local government revenue spent on police protection. These
associations in the final model were in the directions anticipated from their bivariate associations
(e.g., cases where racial origin of hair tests were done were more likely to be exculpatory), yet failed
to achieve statistical significance. The remaining variables in the final predictive model, which were
included only as statistical controls, were not significantly predictive of exculpatory DNA results;
these included ABO blood group typing, convicted offender was a stranger, number of victims, and
convicted offender age.
.

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Table 19. Final Multivariate Logit Model Predicting Exculpatory DNA Testing Results
Beta
SE
Model N
Akaike information criterion (AIC) correcteda
Nagelkerke R-square
ABO blood group typing included convicted offender
Enzyme typing done in case
Racial origin of hair analysis done in case
Murder is most serious offense
Age of case in years (time from offense to Jan. 1, 2012)
Location of offense: Indoors (inside home/apartment/building)b
Convicted offender was stranger (not known prior to day of crime)b
Number of convicted offender convicted for this crime
Number of victims
Convicted offender age
Constant

Exp(B)

162
128.10
0.400
0.647
-2.218*
0.518
1.424†
-0.221**
1.372*
-1.293
2.120***
-0.572
0.055

0.546
1.117
0.551
0.841
0.084
0.659
0.848
0.550
0.945
0.043

1.615

3.149

1.910
0.109
1.679
4.152
0.802
3.942
0.275
8.331
0.565
1.057

Notes: K. P. Burnham and D. R. Anderson, 2002, Model Selection and Multimodel Inference: A Practical Information-Theoretic Approach,
2nd ed. Springer-Verlag.
b Missing values for 24percent to 27 percent of convictions. Significance levels defined as † p<.10, * p<.05, ** p<.01, ***
p<.001.
a

Using results from the final model presented in Table 19, we calculated the predicted
probability that each sexual assault conviction in the final model would yield exculpatory DNA
testing results. Based on these calculations, we note that these predicted probabilities ranged from
.001 to .877, with a mean of .167 and median .072.
Focusing first on the five statistically significant relationships in the final model, we note that
controlling for all other known factors, the average predicted probability that determinate DNA
testing on sexual assault convictions in this sample would yield exculpatory results was—






.08 for convictions where enzyme typing was done in the case, compared to .18 for
convictions where it was not (difference of negative .10);
.26 for convictions where murder was the most serious offense, compared to .15 when
rape was the most serious offense (difference of .11);
.31 for convictions when the case was 24 to 29 years old, .16 when the case was 30 to 34
years old, and .09 when the case was 35 to 39 years old (difference ranging from .07 to
.22);
.21 for convictions where the offense occurred indoors, compared to .10 for convictions
where it occurred outdoors (difference of .11); and
.83 for cases where three suspects were convicted, .40 for cases where two suspects were
convicted, and .12 if only one suspect was convicted (difference ranging from .28 to .71).

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Clearly the number of convicted suspects had the strongest relationship to exculpatory DNA testing
results in this final model. Notably, of the sexual assault convictions with determinate results, 8
percent of those exculpatory involved three convicted suspects, compared to 4 percent of those
inculpatory; 30 percent of those exculpatory ones involved two convicted suspects, compared to 8
percent of those inculpatory; and 63 percent of those exculpatory involved just one convicted
suspect, compared to 89 percent of those inculpatory. The other four relationships between
predictors and exculpatory results were of relatively equal weighting.
In addition to the predicted probabilities above, the average predicted probabilities of
exculpatory DNA results for variables that did not achieve statistical significance in the final model
were as follows:






.18 for convictions where ABO blood group typing included the convicted offender,
compared to .15 for convictions where it did not;
.24 for convictions where racial origin of hair analysis was done in the case, compared to
.09 for convictions where it was not;
.16 for convictions where the convicted offender was a stranger, compared to .29 for
convictions where he was known to the victim;
.18 for convictions where there was one victim, .09 when there were two victims, and .04
or less when there were three or more victims; and
.14 for convictions where the convicted offender was 14 to 20 years old, .17 where the
convicted offender was 21 to 29 years old, and .20 where the convicted offender was 30
years or older.

Though none of these differences achieved statistical significance in the final model, the most
sizable in the data were those involving racial origin of hair analysis and number of victims.
Does the same model predict exculpatory DNA testing results supporting exoneration, as
opposed to inculpatory results?
In this section, we take the same predictor variables from the final model predicting exculpatory
DNA results (as shown in Table 19) and use them in a model predicting convictions with
exculpatory results that support exoneration. In other words, whereas in the last section we focused
on any exculpatory/elimination evidence, as compared to inculpatory evidence, here we look only at
those exculpatory eliminations that support exoneration (again, as compared to inculpatory
outcomes).
In Table 20, we find that the results are virtually identical to those looking at all convictions
with exculpatory outcomes, with two exceptions. In the convictions with exculpatory results that
support exoneration, whether murder is the most serious offense is no longer statistically significant,
and the whether the convicted offender was a stranger is now significant. The other three significant
predictors (location of the crime, number of suspects, and enzyme typing done) remain significant,
and the odds ratios of each are slightly greater than in Table 19.

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Table 20. Final Multivariate Logit Model Predicting Exculpatory DNA Testing Results,
Estimated Only on Convictions with Exculpatory Results that Support Exoneration (versus
Inculpatory)
Beta
SE
Exp(B)
Model N
158
Akaike information criterion (AIC) correcteda
107.83
Nagelkerke R-square
0.476
ABO blood group typing included convicted offender
Enzyme typing done in case
Racial origin of hair analysis done in case
Murder is most serious offense
Age of case in years (time from offense to Jan. 1, 2012)
Location of offense: Indoors (inside
home/apartment/building)b
Convicted offender was stranger (not known prior to day of
crime)b
Number of convicted offenders convicted for this crime
Number of victims
Convicted offender age
Constant

0.898
-2.382†
0.702
1.196
-0.325**

.626
1.284
.647
1.017
.102

2.455
.092
2.018
3.308
.723

1.881*

.824

6.560

-1.594†

.946

.203

2.308***
-0.430
0.071
3.416

.608
1.097
.048
3.618

10.056
.651
1.074

Notes: a K. P. Burnham and D. R. Anderson, 2002, Model Selection and Multimodel Inference: A Practical Information-Theoretic
Approach, 2nd ed. Springer-Verlag.
b Missing values for 24 percent to 27 percent of convictions. Significance levels defined as † p<.10, * p<.05, ** p<.01,
*** p<.001.

Again, we used results in Table 20 to calculate the predicted probability that each conviction
would result in DNA testing results that were exculpatory supporting exoneration. Here we discuss
those probabilities, which ranged from .0004 to .867 with a mean of .145 and median .049, for each
of the significant predictors. While holding all other predictors constant, the predicted probability of
exculpatory supporting exoneration results was as follows:






.08 for convictions where enzyme typing was done in the case, compared to .16 for
convictions where it was not (difference of negative .08);
.32 for convictions when the case was 24 to 29 years old, .13 when the case was 30 to 34
years old, and .07 when the case was 35 to 39 years old (difference ranging from .06 to
.25);
.19 for convictions where the offense occurred indoors, compared to .07 for convictions
where it occurred outdoors (difference of .12);
.13 for convictions where the convicted offender was a stranger, compared to .29 for
convictions where he was known to the victim (difference of .16); and
.79 for cases where three suspects were convicted, .33 for cases where two suspects were
convicted, and .11 where only one suspect was convicted (difference ranging from .22 to
.68).

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Again, the number of convicted suspects has the substantively strongest relationship, followed by
age of the case, location of the offense, stranger offenders and enzyme typing.

Case Studies
Next, we present summaries of several cases in this data set (in no particular order) to illustrate the
three types of determinate post-conviction DNA testing outcomes defined by UI researchers:
inculpatory, exculpatory but insufficient for exoneration, and exculpatory and supportive of
exoneration (which includes all known exonerations).43 Available information on these cases was
limited to data present in the DFS forensic files, which mainly included basic facts about the crime,
results of the original forensic tests, and the results of more recent DNA analysis. Therefore, except
in unusual situations where there was a subpoena for the expert witness or record of a court
appearance, or if the case was included in our three-court pilot study, we cannot qualitatively
understand how the original forensic test results influenced the original investigation or prosecution.
Given these limitations, we identify the following case studies as exoneration (if the convicted
suspect has been officially exonerated by the Commonwealth of Virginia), exculpatory and
supportive of exoneration, or may be exculpatory but insufficient to support exoneration.
What follows is not an illustration of a random sample of cases taken from our sample.
Rather, we have sought to highlight specific examples, including all four known exonerations in the
data set, to show how the available forensic evidence fits the broader pattern of facts in the case.
These examples alternatively show the power—and limitations—of post-conviction DNA testing in
helping inform a review of old cases resulting in a conviction where physical evidence was retained.
Case Study #1: Exoneration
In 1984, a non-English-speaking white female was allegedly sexually assaulted in a courtyard by a
black male stranger. The police identified two black male suspects in the case. The forensic examiner
(who was called to testify) conducted blood group typing on the victim PERK and identified a
blood type match to suspect 1’s reference sample. Suspect 1 was arrested two months after the
offense, and suspect 2 was never arrested. Suspect 1 had a court-appointed attorney and was
convicted after a four-day jury trial. He appealed the conviction, but it was upheld. DNA testing
results conducted for this study eliminated suspect 1 as the contributor of the male DNA profile in
the victim PERK. A subsequent search of the Virginia DNA database identified suspect 2 as the
true offender. Suspect 1 was pardoned and released from prison in 2005.
Case Study #2: Exoneration
In 1979, a white female was awakened in her home and allegedly sexually assaulted by an unknown
black male suspect. A suspect was identified and charged. Again, the forensic examiner determined
that the suspect’s blood type matched the blood type from the questioned evidence collected at the
crime scene. A forensic examiner also determined that the suspect’s hair and the hair found at the
scene belong to the same racial class. The suspect was convicted and sentenced to 16 years in prison.
In the course of this study, a male DNA profile developed from textiles found at the crime scene
and a vaginal swab from the victim PERK eliminated the convicted offender as the contributor of
the profile. The DNA profile did not hit to any individual in the FBI’s Combined DNA Index

43

Outcome 1, Indeterminate, is explained in the Methodology section.

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System (CODIS), and the real perpetrator remains unknown. The convicted suspect was exonerated
in 2011.
Case Study #3: Exoneration
In 1979, a white female was allegedly sexually assaulted by an unknown white man. The victim
identified the suspect the day after the assault. A forensic examiner conducted blood group typing
and a racial origin of hair analysis in the case. Blood group typing did not match the suspect. All
questioned hairs were classified as Caucasian; however, both the suspect and victim were white. The
suspect had a criminal record prior to this case (but not for sexual assault), and he was convicted and
sentenced to 25 years. However, DNA testing during the course of this project identified a profile
from a sperm fraction of the victim’s vaginal swab that eliminated the convicted suspect as the
source of that DNA. This finding was used to support exoneration. Unfortunately, while the profile
could be used to exclude the original suspect, it was not suitable for searching in CODIS and no
new suspect has been identified.44
Case Study #4: Exoneration
In 1984, an unknown black male broke into a church, threatened a white female with a knife, and
allegedly sexually assaulted her. A suspect was identified days later by the victim and was arrested.
The forensic examiner conducted blood group typing and determined the racial origin of hairs. The
suspect blood type matched the blood type found at the crime scene. Hairs found in the victim
PERK were determined to be Caucasian and therefore, the suspect was eliminated as the source of
those hairs. However, post-conviction DNA testing for this study identified a profile developed
from the sperm fraction of vaginal swabs in the victim PERK that eliminated the convicted suspect
as the source. This profile also hit to another offender in CODIS, and the convicted suspect was
exonerated.
Case Study #5: May Be Exculpatory and Supporting/Inculpatory
In 1977, a white female was allegedly sexual assault and robbed by two black male strangers. Two
suspects were arrested the day after the assault; both had prior records and knew each other. Blood
group typing included suspect 1 but not suspect 2 as the source of evidence collected from the
victim PERK. The victim identified both suspects but only after undergoing hypnosis. Suspect 1
initially pled guilty but later withdrew the plea. Both suspects had court-appointed attorneys, were
convicted by jury trial and were sentenced to more than 60 years (suspect 2 had a longer sentence
than suspect 1). Both suspects appealed their conviction; suspect 1 appealed four times and suspect
2 appealed two times. DNA testing for this study identified a male profile from the vaginal swabs of
the victim PERK. Suspect 1 was included as a contributor of this profile, while suspect 2 was
eliminated. Thus, the DNA results were inculpatory for suspect 1 and may be supportive of
exoneration for suspect 2. However, since the victim reported two attackers and only one DNA
profile was developed, the elimination of suspect 2 from the PERK suggests that other information

44 An often overlooked value of DNA analysis is that a very partial profile can be used to eliminate a suspect. DNA
profiles are produced from commercial kits that target a set number of loci. For example, the kit PowerPlex 16™
develops a 16-loci profile and includes the 13 targeted for CODIS entry. The more loci shared between matching
profiles, the stronger the association is between them. However, only a few loci are necessary to exclude a person as the
source of that biological material. If a partial profile (i.e., less than the targeted number of loci) is developed (say six loci)
and those loci do not match a known standard, that subject can be eliminated as the source of that DNA.

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is necessary for exoneration. This case example illustrates how an exculpatory result in the VA
model is the starting point for a determination of wrongful conviction, not the terminus.
Case Study #6: May Be Exculpatory and Supporting
In 1977, a black male allegedly forced his way into a white female’s home at gunpoint and sexually
assaulted her. The forensic examiner conducted blood group typing and racial origin of hair
classification. No blood type match was found. Hairs recovered from the crime scene were of the
same racial class as the suspect. However, other characteristics of the hairs were not consistent with
the suspect’s samples. The suspect was convicted in a jury trial and sentenced to five years, despite
not matching the victim’s description of her attacker and having an alibi supported by several
witnesses. DNA testing for this study identified a male profile from a sperm fraction on the victim’s
panties. The convicted suspect was eliminated as a possible source of the profile, which hit to
another offender in CODIS. Though the convicted suspect has not been exonerated yet, the state is
currently reviewing the case for potential exoneration.
Case Study #7: May Be Exculpatory and Supporting/Inculpatory/Indeterminate
In 1976, a white female was allegedly sexual assault in her home by three male strangers. Three
suspects were arrested within days of the assault. Forensic testing compared suspect reference blood
and hair samples to crime scene evidence. Suspect 1’s hair samples were determined to be of the
same racial class as those collected at the crime scene, but his blood type did not match the
questioned evidence. However, suspect 2’s blood type and suspect 3’s blood type matched biological
evidence collected at the crime scene. Suspect 1 had a court-appointed attorney and did not confess
or enter a guilty plea. He was convicted in a jury trial and sentenced to more than 25 years. Suspect 2
confessed while under the influence of drugs (and was later diagnosed as mentally ill), and suspect 3
(who was also later diagnosed as mentally ill) pled guilty. All three suspects appealed their
conviction. DNA testing produced different outcomes for each suspect. A profile from a male
contributor was developed from the victim’s underwear, and suspect 1 was eliminated as the source
while suspect 2 was identified as a contributor. No reference profile was developed for suspect 3, so
he could not be included or excluded as a contributor of any profile. Thus, UI researchers coded
suspect 2’s conviction as inculpatory, suspect 3’s as indeterminate, and suspect 1’s as exculpatory
supporting exoneration. Again, however, we note that since the victim reported three attackers and
only one profile was developed, elimination of convicted suspect 1 from DNA found in the PERK
suggests that other information may be necessary for an exoneration.
Case Study #8: May Be Exculpatory but Insufficient
In 1986, when an older black male victim was killed, the only suspect in the case was also an older
black male. At the time, DFS examined a knife and bullet found at the crime scene, but was only
able to conduct blood group typing on stains from the suspect’s clothes. The blood found at the
scene was the same blood type as the suspect but not as the victim. The suspect was charged with
manslaughter and sentenced to five years. DFS obtained the convicted suspect’s profile from the VA
DNA data bank and compared it to DNA from the bloodstain on his clothes. The suspect could not
be eliminated as the source of that blood. However, the convicted suspect’s profile was eliminated as
the contributor of DNA found on the knife. Still, without a victim reference sample DFS was
unable to conclude whether the DNA profile present on the knife belonged to the victim or to an
unknown suspect. If the knife’s profile belonged to another suspect, the results are exculpatory and
supportive of exoneration; however, if the knife’s profile belonged to the victim, there is no
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exculpatory evidence in favor of the convicted suspect. Additionally, it is not known whether any
nonforensic factors in the original case link the convicted suspect to the knife or if he admitted to
being at the scene of the crime. Thus, these DNA testing results were classified as exculpatory (given
elimination of the suspect’s profile on the questioned evidence) but insufficient for exoneration.

Discussion
This study is the first to analyze DNA testing results for an unbiased sample of serious person crime
convictions involving biological evidence. Previous analyses of post-conviction DNA testing results
have been based on samples principally derived from detected wrongful convictions alone or used
insufficient proxies for actual wrongful convictions, with little available evidence about nonexonerations for comparison (Gould and Leo 2010).
Usually, post-conviction DNA testing is performed only after extensive legal review with
regard to the potentially probative value of the evidence. As a result, almost all instances of known
wrongful convictions prior to this study were those detected after innocence was actively claimed.
Innocent persons who have not actively pursued exoneration have to date remain undetected. In
contrast, this study identified potential wrongful convictions based on an unbiased sampling of
violent crime convictions—the governor of Virginia ordered DNA testing on all eligible convictions,
regardless of whether evidence pointed to the guilt or innocence of a convicted suspect. This
approach allowed us to make predictions about the efficacy of DNA testing at reaching determinate
conclusions about the rightful or wrongful nature of such convictions, and ultimately, at the
estimated rate of wrongful conviction in homicides and sexual assaults in Virginia during the years
studied.
The VA model of post-conviction DNA testing takes the traditional model and turns it on
its head. As a result, the results of the DNA testing are a starting point for detecting wrongful
convictions, rather than an endpoint. As illustrated in Figure 1, exculpatory results should be the
trigger for additional investigation by law enforcement or prosecutor’s offices to determine the
probative value of that exculpatory result. And for those that hold sufficient weight, courts should
proceed toward exoneration or other post-conviction relief. These post-DNA testing activities were
not supported by this NIJ grant funding, and were therefore not observed as part of this research.
Our results from this study are consistent with some prior literature on the influence of
forensic evidence on conviction. Our findings both support and dispute Garrett’s (2008) claim that
some types of forensic evidence (including hair comparisons) are particularly unreliable. Our
findings support this claim only for racial origin of hair testing. All other connections to those
convicted by other forensic methods were not associated with exculpatory results. Inculpatory
results from the original forensic testing, including ABO typing, microscopic hair analysis,
fingerprints, and ballistics, were not associated with exculpatory results from post-conviction DNA
testing. However, an inculpatory result from the racial origin of hairs was a predictor of exculpatory
results in the bivariate comparison but not in the final multivariate model. Additionally, an
inculpatory result from the enzyme typing analysis was a predictor of inculpatory results from DNA
testing in the final multivariate model.

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Within the convictions with determinate DNA testing results, we distinguished between
outcomes that were exculpatory and supportive of exoneration and outcomes that were exculpatory
but insufficient. This is an important distinction, but does not mean that all supportive exculpatory
outcomes have results that could lead to exoneration. An outcome that is exculpatory and
supportive of exoneration means that DNA testing conclusively eliminated the suspect as
contributor of any evidence for which there were DNA testing results. Exculpatory but insufficient
outcomes have DNA results that are more inconclusive (for example, the suspect could be
eliminated from one swab in the PERK, but other contextual factors in the case may make this
finding highly non-probative). This distinction is important for interpreting our results, particularly
when it comes to estimating the rate of wrongful conviction. Essentially, the rates presented in this
report are an upper bound.
As discussed previously, one of the main limitations of this data set is the fact that
determinate results were not obtained from DNA testing in about two-thirds of the convictions.
This attrition may bias results to the extent that unobserved heterogeneity related to an
indeterminate finding is also related to the likely outcome of the DNA testing. Therefore, our
biggest data limitation is omitted variable bias, primarily the lack of court data. We believe that our
analysis would have been greatly improved by additional court variables (particularly method of
conviction (jury/bench trial or guilty plea)), type of defense attorney (court-appointed or retained),
whether the offender confessed or gave incriminating statements, victim and eyewitness
identification, offender’s prior record and mental health problems, and results from those appeals
and would have allowed us to test theories put forth in prior studies, particularly about the impact of
witness identification, trial type, and confessions on wrongful conviction (Conners et al. 1996;
Garret 2008; Gross et al. 2005). We recommend further investigation of court data to address these
limitations.
The physical evidence that was retained in these VA cases was very old and in many
instances had already been subject to forensic testing. As a result, two-thirds yielded no determinate
results. The central challenge of this study is how to interpolate the results of the one-third of
convictions that yielded determinate results to the two-thirds of convictions that did not. While we
are confident that these convictions are an unbiased sample of sexual assaults and homicides from
1973 to 1987 in VA and thus are generalizable to all convictions of the same type from the same
period, we are less confident that the convictions with determinate results are a random sample of all
convictions from the period. Thus, it is much less clear what the findings for the convictions with
determinate outcomes mean for those with indeterminate outcomes.
This issue is critical to the determination of a rate of wrongful conviction, which is the ratio
of convictions with exculpatory results that support exoneration over the number of convictions
examined. Both of those numbers are debatable from our study. In order to calculate a rate of
wrongful conviction, we would need to know how many of the convictions with indeterminate
DNA testing results would have eliminated the convicted offender as the contributor of probative
evidence. As it stands, the numerator in our wrongful conviction ratio is 38 and the denominator is
715 (if all convictions that were tested is the denominator) or the numerator is 33 and the
denominator is either 422 (if all sexual assault convictions are included in the denominator), or 227
(if only sexual assaults with a determinate outcome are included in the denominator).

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We believe that two findings are not in dispute:


First, we find that in convictions from VA between 1973 and 1987 where evidence was
retained in a sample of homicides and sexual assault cases that resulted in a conviction,
the suspect is eliminated as a contributor for a probative evidence item, and that is
supportive of exoneration in 5 percent of convictions.



Second, we find that in convictions from VA between 1973 and 1987 where evidence was
retained in an unbiased sample of convictions for sexual assault cases, the convicted
offender is eliminated as a contributor for a probative evidence item, and that is supportive
of exoneration in between 8 and 15 percent of convictions.45 We note again that additional
facts about the case not included in the forensic file may ultimately include the convicted
offender. However, given that these are sexual assault convictions where the profile was
determined to be male and excluded the convicted offender, we anticipate this will be
relatively rare.

We also believe that since fewer than 10 percent of homicides where there was no sexual assault
have a determinate result after DNA testing was performed on questioned evidence, the second
finding is better supported by the data than the first. The second finding then leads to a follow-up,
which is, where between 8 and 15 percent is the real rate of wrongful conviction?
Thus, the critical issue is how to impute outcomes for the convictions where evidence was
indeterminate. Logically, there are three possible outcomes for the convictions with indeterminate
results. First, it is possible that the 38 convictions with probative evidence that eliminates the
convicted offender as the source include all of the convicted offenders who would have been
eliminated had a determinate result been obtained. Second, it is possible that there are others who
had indeterminate results who would have been eliminated as the contributor of probative evidence
had a determinate result been obtained. However, the cohort of convictions with determinate
evidence may have included a disproportionate number of convictions that eliminated the convicted
offender. This would be the case, for instance, if cases with a PERK were more likely to be
determinate and included a disproportionate number of convicted offenders who were eliminated as
the contributors of probative evidence. Third, it may be the case that the cohort with a determinate
result effectively approximates a random sample of all convictions, and thus it is appropriate to
interpolate the determinate results on to the convictions with indeterminate results. There is a fourth
possible outcome, that the convictions with determinate results underestimate the rate of elimination
in the convictions with indeterminate results. However, there is little support for this claim in the
data we have examined. Given the differences in the yield of physical evidence (e.g., the likelihood
physical evidence would generate a profile and that profile would be determinate) described in Table
6, it seems likely that the answer lies in the second option, somewhere between the two extremes.
The 8 and 15 percent statistics are not a range; rather, they are estimates for two different policy questions. The first
answers the question, “What percentage of cases would eliminate a convicted offender if DNA evidence in a sample of
convicted offenders with retained evidence were tested?”The convicted offender was eliminated as the source of
questioned evidence in 33 out of 422 convictions (8 percent), and that elimination was supportive of exoneration. If the
same question were asked, but only about those cases where a determination about the evidence could be made, than the
answer would be that the convicted offender was eliminated as the source of questioned evidence in 33 out of 227
convictions (15 percent) where a determination could be made from the DNA analysis and that elimination was
supportive of exoneration.
45

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As was discussed in the report, it is technically possible to use regression models to impute
the likely outcomes for each conviction with an indeterminate result. We chose not to do so and
would counsel others to do the same. We follow Allison (2001), who cautions that data that are
missing more than 15 percent of the time cannot be assumed to be missing at random. In this case, a
determinate outcome is missing two-thirds of the time. Thus, we cannot assume that the convictions
with indeterminate results are similar enough to convictions with determinate results to model their
expected outcomes. Unless we can demonstrate that the finding of determinate/indeterminate is
unrelated to DNA testing outcomes or we are able to observe these differences and account for
them in our statistical models, such modeling is not appropriate. Since there are significant
predictors of whether DNA testing results are determinate or indeterminate, and there are
significant predictors of attributes that are related to convictions outcome, it is reasonable to
presume that they differ on unobservable attributes as well. More important, while we can explain a
substantial amount of the variation in the DNA testing outcomes, our models explain very little of
the variation in whether a DNA testing result was determinate and the presence of unobservable
heterogeneity likely lead to biased results.
It is tempting to make a back-of-the-envelope calculation to estimate where between 8 and
15 percent the truth lies. To do so, one could simply assume that the relationship between the type
of evidence in convictions with determinate results and the outcome (inclusion/elimination) is the
same in convictions with determinate and indeterminate results. Then, one would need only to look
at the prevalence of evidence types in all convictions (determinate and indeterminate) to estimate the
wrongful conviction rate. So, for instance, if X percent of convictions with a PERK are found to be
eliminations, and the prevalence of PERK is the same in convictions with determinate and
indeterminate results, then we could simply interpolate those same convictions outcomes for those
with indeterminate results. However, our data suggest that many factors are related to the conviction
outcome beyond evidence type, and such simplifying assumptions are unlikely to yield robust
estimates.
We note that a standard question in social science is whether an observed outcome is large
or not. In this case, given that even our most conservative estimate of exclusion in support of
exoneration is larger than previous estimates, we believe our result is unquestionably a large number.
Even our most conservative estimate suggests that 8 percent (or more) of sexual assault convictions
in a 15-year period may have been wrongful. That means hundreds, if not more than a thousand,
convicted offenders may have been wrongfully convicted.46 That also means hundreds (if not more)
victims have not received the just result, as previously believed. Therefore, whether the true rate of
potential wrongful conviction is 8 percent or 15 percent in sexual assaults in Virginia between 1973
and 1987 is not as important as the finding that these results require a strong and coordinated policy
response.
Finally, we encourage policymakers to consider one final effect of this study on victims of
sexual assault in VA between 1973 and 1987. The identities of the convicted offenders who were
excluded from DNA testing as the contributor of questioned evidence cannot be shared due to the
need to protect the confidentiality of the human subjects involved in this study. Thus, the number of
victims of sexual assault who can be legitimately concerned that justice was not done in their case
In order to determine how many wrongful convictions there are in the period, we would need to know how many of
the more than 20,000 forcible rapes resulted in a felony conviction. That statistic is not available.
46

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includes all victims of sexual assault where the case resulted in a convicted offender, not just in cases
where a convicted offender was eliminated. Only in cases where a convicted offender has been
exonerated can that distinction be publicly observed.

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