VALCRI

Last updated
The project is funded by the European Commission European Commission.jpg
The project is funded by the European Commission

Visual Analytics for Sense-making in Criminal Intelligence Analysis (VALCRI) is a software tool that helps investigators to find related or relevant information in several criminal databases. [1] [2] The software uses big data processes to aggregate information from a wide array of different sources and formats and compiles it into visual and readable arrangements for users. [3] It is used by various law enforcement agencies and aims to allow officials to utilize statistical information in their operations and strategy. [4] [3] The project is funded by the European Commission and is led by Professor William Wong at Middlesex University. [5]

Contents

Features

VALCRI can automatically search numerous databases using dedicated search engines. Previously, investigators would need to employ an average of 73 SQL queries and wait up to three days to find the right cases. [6] The tool utilizes machine learning mechanisms to screen through masses of unstructured data to identify similarities between cases, and performs associative searching to comes up with reports based on the search criteria of users. [7]

Data visualization

VALCRI can present data and information in visual formats such as maps, timelines, dispersion diagrams, and process charts. [5] This creates an analyst dashboard that is designed to be integrated within the workforce and allow for investigative reasoning based on database information. [7] The visualizations are interactive and encourage cooperative input from human analysis.

VALCRI also employs algorithms such as PCA, MDS, and t-SNE to embed data points into graphical representations. [8] This feature allows for the statistical and mathematical calculation of similarity and correlation levels between different crime data sets through different algorithmic models which each have their own strengths and weaknesses. [9]

Concerns

During the development of VALCRI, an Independent Ethics Board (IEB) and Security, Privacy, and Legal Group (SEPL) was created to monitor potential ethical challenges and roadblocks that the project would introduce. [10] With the specialists in these boards, there were numerous concerns that were identified in respect to potential ethics and legality issues. [10]

One issue that was identified by these boards was potential complications with human privacy. [11] With the advent of a comprehensive database system that would be able to share billions of different data points for law enforcement, VALCRI faces potential roadblocks in navigating through different regional policies and laws regarding data privacy and security. [11] This potential issue has been addressed in VALCRI by creating a dedicated group supervising data management policy in the software. [12]

Cognitive and sense-making bias

VALCRI's data analysis capabilities offer criminal analysts a wider set of data points to base their conclusions on. Vienna University of Technology's research based on 120 case studies introduces the risk of cognitive and sense-making bias playing a significant role in influencing the conclusions that law enforcement agents draw, based on the visualizations provided by VALCRI. [13] These risks can be mitigated in VALCRI by redesigning machine learning models and implementing de-biasing mechanisms such as Klein's data frame model so that it becomes easier to identify cognitive bias and adjust analysis objectives based on the findings. [13]

See also

Related Research Articles

<span class="mw-page-title-main">Surveillance</span> Monitoring something for the purposes of influencing, protecting, or suppressing it

Surveillance is the monitoring of behavior, many activities, or information for the purpose of information gathering, influencing, managing or directing. This can include observation from a distance by means of electronic equipment, such as closed-circuit television (CCTV), or interception of electronically transmitted information like Internet traffic. It can also include simple technical methods, such as human intelligence gathering and postal interception.

<span class="mw-page-title-main">Facial recognition system</span> Technology capable of matching a face from an image against a database of faces

A facial recognition system is a technology potentially capable of matching a human face from a digital image or a video frame against a database of faces. Such a system is typically employed to authenticate users through ID verification services, and works by pinpointing and measuring facial features from a given image.

<span class="mw-page-title-main">Crime mapping</span>

Crime mapping is used by analysts in law enforcement agencies to map, visualize, and analyze crime incident patterns. It is a key component of crime analysis and the CompStat policing strategy. Mapping crime, using Geographic Information Systems (GIS), allows crime analysts to identify crime hot spots, along with other trends and patterns.

Semantic AI is a privately held software company headquartered in San Diego, California with offices in the National Capitol Region. Semantic AI is a Delaware C-corporation that offers patented, graph-based knowledge discovery, analysis and visualization software technology. Its original product is a link analysis software application called Semantica Pro, and it has recently introduced a web-based analytical environment called the Cortex Enterprise Intelligence Platform, or Cortex EIP.

<span class="mw-page-title-main">Digital forensics</span> Branch of forensic science

Digital forensics is a branch of forensic science encompassing the recovery, investigation, examination, and analysis of material found in digital devices, often in relation to mobile devices and computer crime. The term "digital forensics" was originally used as a synonym for computer forensics but has expanded to cover investigation of all devices capable of storing digital data. With roots in the personal computing revolution of the late 1970s and early 1980s, the discipline evolved in a haphazard manner during the 1990s, and it was not until the early 21st century that national policies emerged.

<span class="mw-page-title-main">Crime analysis</span>

Crime analysis is a law enforcement function that involves systematic analysis for identifying and analyzing patterns and trends in crime and disorder. Information on patterns can help law enforcement agencies deploy resources in a more effective manner, and assist detectives in identifying and apprehending suspects. Crime analysis also plays a role in devising solutions to crime problems, and formulating crime prevention strategies. Quantitative social science data analysis methods are part of the crime analysis process, though qualitative methods such as examining police report narratives also play a role.

<span class="mw-page-title-main">Federal Criminal Police Office (Germany)</span> German federal investigative police agency

The Federal Criminal Police Office of Germany is the federal investigative police agency of Germany, directly subordinated to the Federal Ministry of the Interior. It is headquartered in Wiesbaden, Hesse, and maintains major branch offices in Berlin and Meckenheim near Bonn. It has been headed by Holger Münch since December 2014.

In the United States, fusion centers are designed to promote information sharing at the federal level between agencies such as the Federal Bureau of Investigation, the U.S. Department of Homeland Security, the U.S. Department of Justice, and state, local, and tribal law enforcement. As of February 2018, the U.S. Department of Homeland Security recognized 79 fusion centers. Fusion centers may also be affiliated with an emergency operations center that responds in the event of a disaster.

<span class="mw-page-title-main">Analysis of competing hypotheses</span> Process to evaluate alternative hypotheses

The analysis of competing hypotheses (ACH) is a methodology for evaluating multiple competing hypotheses for observed data. It was developed by Richards (Dick) J. Heuer, Jr., a 45-year veteran of the Central Intelligence Agency, in the 1970s for use by the Agency. ACH is used by analysts in various fields who make judgments that entail a high risk of error in reasoning. ACH aims to help an analyst overcome, or at least minimize, some of the cognitive limitations that make prescient intelligence analysis so difficult to achieve.

Intelligence-led policing (ILP) is a policing model built around the assessment and management of risk. Intelligence officers serve as guides to operations, rather than operations guiding intelligence.

Richards "Dick" J. Heuer, Jr. was a CIA veteran of 45 years and most known for his work on analysis of competing hypotheses and his book, Psychology of Intelligence Analysis. The former provides a methodology for overcoming intelligence biases while the latter outlines how mental models and natural biases impede clear thinking and analysis. Throughout his career, he worked in collection operations, counterintelligence, intelligence analysis and personnel security. In 2010 he co-authored a book with Randolph (Randy) H. Pherson titled Structured Analytic Techniques for Intelligence Analysis.

REBES was the first U.S. American offender profiling software for local crime investigation. This expert system was developed for the Baltimore County Police Department by the Jefferson Institute for Justice Studies to assist the investigation of residential burglaries in the late 1980s. The REBES computer program was discontinued after experimental use in the beginning 1990s.

i2 Group Software companies of the United Kingdom

i2 Group is a UK-based software company that produces visual link analysis software for military intelligence, law enforcement, and commercial agencies. Since 2022, it has been a wholly owned subsidiary of Constellation Software.

<span class="mw-page-title-main">Domain Awareness System</span>

The Domain Awareness System is the largest digital surveillance system in the world as part of the Lower Manhattan Security Initiative in partnership between the New York Police Department and Microsoft to monitor New York City. It allows the NYPD to track surveillance targets and gain detailed information about them, and is overseen by the counterterrorism bureau.

In the United States, the practice of predictive policing has been implemented by police departments in several states such as California, Washington, South Carolina, Alabama, Arizona, Tennessee, New York, and Illinois. Predictive policing refers to the usage of mathematical, predictive analytics, and other analytical techniques in law enforcement to identify potential criminal activity. Predictive policing methods fall into four general categories: methods for predicting crimes, methods for predicting offenders, methods for predicting perpetrators' identities, and methods for predicting victims of crime.

<span class="mw-page-title-main">Social media analytics</span> Process of gathering and analyzing data from social media networks

Social media analytics is the process of gathering and analyzing data from social networks. It is commonly used by marketers to track online conversations about products and companies. One author defined it as "the art and science of extracting valuable hidden insights from vast amounts of semi-structured and unstructured social media data to enable informed and insightful decision making."

<span class="mw-page-title-main">Surveillance issues in smart cities</span>

Smart cities seek to implement information and communication technologies (ICT) to improve the efficiency and sustainability of urban spaces while reducing costs and resource consumption. In the context of surveillance, smart cities monitor citizens through strategically placed sensors around the urban landscape, which collect data regarding many different factors of urban living. From these sensors, data is transmitted, aggregated, and analyzed by governments and other local authorities to extrapolate information about the challenges the city faces in sectors such as crime prevention, traffic management, energy use and waste reduction. This serves to facilitate better urban planning and allows governments to tailor their services to the local population.

<span class="mw-page-title-main">Algorithmic bias</span> Technological phenomenon with social implications

Algorithmic bias describes systematic and repeatable errors in a computer system that create "unfair" outcomes, such as "privileging" one category over another in ways different from the intended function of the algorithm.

Automated decision-making (ADM) involves the use of data, machines and algorithms to make decisions in a range of contexts, including public administration, business, health, education, law, employment, transport, media and entertainment, with varying degrees of human oversight or intervention. ADM involves large-scale data from a range of sources, such as databases, text, social media, sensors, images or speech, that is processed using various technologies including computer software, algorithms, machine learning, natural language processing, artificial intelligence, augmented intelligence and robotics. The increasing use of automated decision-making systems (ADMS) across a range of contexts presents many benefits and challenges to human society requiring consideration of the technical, legal, ethical, societal, educational, economic and health consequences.

Predictive policing is the usage of mathematics, predictive analytics, and other analytical techniques in law enforcement to identify potential criminal activity. A report published by the RAND Corporation identified four general categories predictive policing methods fall into: methods for predicting crimes, methods for predicting offenders, methods for predicting perpetrators' identities, and methods for predicting victims of crime.

References

  1. AI detective analyses police data to learn how to crack cases [ full citation needed ]
  2. Visual Analytics for Sense-making in CRiminal Intelligence analysis [ full citation needed ]
  3. 1 2 Schlehahn, Eva (2017). "The Operationalisation of Transparency in VALCRI" (PDF).
  4. Improvements to machine-intelligence will improve accuracy and speed up police investigations
  5. 1 2 Anslow, Craig; Rooney, Chris; Kodagoda, Neesha; Wong, William (2015). "Police Analyst Workstation". Proceedings of the 2015 International Conference on Interactive Tabletops & Surfaces - ITS '15. New York, New York, USA: ACM Press. pp. 307–311. doi:10.1145/2817721.2823498. ISBN   978-1-4503-3899-8. S2CID   2002596.
  6. Visual analytics for brighter criminal intelligence [ full citation needed ]
  7. 1 2 "Final Report Summary - VALCRI (Visual Analytics for Sense-making in CRiminal Intelligence analysis)". 2018.
  8. Wolfgang, Jentner (2018). "Making machine intelligence less scary for criminal analysts: reflections on designing a visual comparative case analysis tool" (PDF). The Visual Computer. 34 (9): 1225–1241. doi:10.1007/s00371-018-1483-0. S2CID   3342538.
  9. Sacha, Dominik (February 2017). "Applying Visual Interactive Dimensionality Reduction to Criminal Intelligence Analysis" (PDF).
  10. 1 2 Duquenoy, P. (2018). "Addressing Ethical Challenges of Creating New Technology for Criminal Investigation: The VALCRI Project". Societal Implications of Community-Oriented Policing and Technology. SpringerBriefs in Criminology. pp. 31–38. doi:10.1007/978-3-319-89297-9_4. ISBN   978-3-319-89296-2. S2CID   169570412.
  11. 1 2 Marquenie, Thomas; Quezada, Katherine (2019-10-01), "Operationalization of Information Security through Compliance with Directive 2016/680 in Law Enforcement Technology and Practice", Security and Law, Intersentia, pp. 97–128, doi:10.1017/9781780688909.005, ISBN   978-1-78068-890-9, S2CID   213698899 , retrieved 2020-11-03
  12. Marquenie, Thomas (2017). "Data analytics in a police context–addressing legal issues in VALCRI".
  13. 1 2 Pohl, Margit (2014). "Sensemaking and Cognitive Bias Mitigation in Visual Analytics". 2014 IEEE Joint Intelligence and Security Informatics Conference. p. 323. doi:10.1109/JISIC.2014.68. ISBN   978-1-4799-6364-5. S2CID   1758913.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.