PRE2016 4 Groep3

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Group members

Student ID Name
0900940 Ryan van Mastrigt
0891024 René Verhoef
0854765 Lisselotte van Wissen
0944862 Sjanne Zeijlemaker
0980963 Michalina Tataj


Introduction

Problem description

Definitions

Abnormal behaviour
[explanation]
Biometrics
[explanation]


Objectives (/ TO DO list)

Goal: Develop a model for a video-based abnormal behaviour detection program

Objectives of this project:

  • Formulate concrete problem statement
  • Develop overview of the State-of-the-Art
    • List of possible biometrics for detecting abnormal/suspicious behaviour
    • List of different methods available for measuring biometrics (pros/cons, what method works best for what purpose/setting)
    • Current areas of research
    • Problems with current technologies
  • Develop model scenarios for determining abnormal behavior
    • Determine what constitutes abnormal behavior (heavily dependent on context)
    • Determine what scenarios should be looked at (airports, sports stadia, banks)
    • What techniques could be used (pros/cons, possible new ideas)
  • Develop USE aspects
    • Users:
      • Develop easy-to-understand graphical interface for primary users
      • Maintain sense of participation in primary users
      • Conduct survey among general public to research support of such an application and to probe stance on privacy vs security
      • Incorporate findings into design
    • Society:
      • Look into societal advantages (decreased criminal/terrorist activity, global sense of security, decrease in racial/religious tensions)
      • Look into societal disadvantages (decrease in (perceived) privacy)
      • Incorporate findings into design
    • Enterprise:
      • Make sure model is economically feasible and can compete with current systems
      • Look into advantages/disadvantages for enterprises
      • Incorporate findings into design
  • Finalize actual model design
  • Create final presentation

The main goal of the model is to provide a general structure of a program which is capable of identifying suspicious persons for security applications. The method should be based on biometrics which can be used to determine abnormal behavior in order to obtain a higher success rate than comparable human-based surveillance.

The objectives of the model are:

  • Technical objectives:
    • Decrease false-negative rate compared to human-based surveillance
    • Decrease false-positive rate compared to human-based surveillance
    • Provide results to primary user(s) (security guards/police)
  • USE objectives:
    • Users:
      • Provide easy-to-understand information to primary user
      • Provide a higher sense of security (secondary user)
    • Society:
      • Decrease terrorist activity
      • Higher global sense of security
      • Higher crime prevention
      • Decrease racial/religious tensions
    • Enterprise:
      • Create a system which is better than current systems, in order to sell to users
      • Be economically feasible
      • Decrease damage caused to assets (such as buildings) and maintain company reputation

State-of-the-art

Possible biometrics for detecting abnormal behavior in crowds

In order to be able to detect abnormal behavior certain characteristics are required in order to identify agents in a a scene. Such characteristics are based on either physiological or behavioral characteristics and are generally referred to as biometrics. In order to asses the biometric the following conditions can be used:[1]

  • Universality (every person in the scene should posses the trait)
  • Uniqueness (it has to be sufficiently unique so that the agents can be distinguished between one another)
  • Permanence (the trait should not vary too much over time)
  • Measurability (the trait should be relatively easy to measure)
  • Performance (relates to the speed, accurateness and robustness of the technology used)
  • Acceptability (the subjects should be accepting towards the technology used)
  • Circumvention (It should not be easy to imitate the metric)


Most research on identifying behavior via computer vision techniques are focused on non-crowded situations. The subject is either isolated or only a very small number of people are present. However, most of the conventional computer vision methods are not appropriate for use in crowded areas. This is partly due to the fact that people display different behavior in crowd context. As a result, some individual characteristics can no longer be used, but new collective characteristics of the crowd as a whole now emerge. Another big factor is the difficulty of identifying and tracking individuals in a crowd context. This is mostly due to occlusion of (parts of) the subject(s) by objects or other agents. The quality of the video image and the increased processing power needed to track individuals are also important factors. [2]


Most current research focuses on tracking of the people in the crowds. The individual tracking of people has proven to be difficult in a crowd context. Many different methods have been proposed for individual tracking and while these tend to work satisfactory for low to moderately crowded situations, they tend to fall flat in higher density crowds. There are also models which try to use general crowd characteristics to detect anomalies, but these tend to ignore singular abnormalities and are better suited for detecting general locations in the scene which contain anomalies, for example where a fire has broken out.[2]


There are promising models that try to combine a bit of both extremes. There is a model which uses a set of low-level motion features to form trajectories of the people in the crowd, but uses an additional rule-set computed based on the longest common sub-sequences [3]. This results in a system that is capable of highlighting individual movements not coherent with the dominant flow. Another paper created an unsupervised learning framework to model activities and interactions in crowded and complicated scenes [4]. They used three elements: low-level visual elements, "atomic" activities, the most fundamental of actions which can not be further divided in sub-activities, and interactions. This model was capable of completing challenging visual surveillance tasks such as determining abnormalities.

Common problems in crowded scenes, such as occlusion of the subjects, can be prevented by moving to a multi-camera surveillance system. Having different angles of the same scene available allows the system to better identify and track subjects. Dynamic cameras (cameras able to turn and zoom in and out) should be able to increase the efficiency of identifying suspicious persons by for example zooming on on the area. However, the use of multiple cameras brings new problems with it. It is difficult to calibrate camera view with significant overlap and to compute their topology. Calibrating camera views which are disjoint and where objects move on multiple ground planes has proven to be challenging. Most research on video surveillance assume a single-camera view, even though multiple-camera surveillance systems can better solve occlusions and scene clutters. Most research on multi-camera systems are based on small-camera networks.[5]

Approach

Planning

In order to keep track of the progress of the project and set deadlines for our goals we have made a Gantt chart. This chart shows what tasks are done during what time. Gantt chart PRE 16 Q4 group3.png


We also made a Resource Gantt chart that shows how tasks are divided over the group members. Gantt chart resources PRE 16 Q4 group 3.png

Milestones

We consider several milestones based on the tasks that lay before us as can be seen in the Gantt chart in the Planning section:

  • Finished the research into what defines abnormal Behaviour. (planned by the end of week 2)
  • Finished the research into the existing methods for biometric scanning. (planned by the end of week 3)
  • Finished analysing the USE aspects that our project brings with it. (planned by the end of week 3)
  • Having developed a model for the detection of abnormal behaviour based on previous research and analyses. (planned by the end of week 6)
  • Holding the final presentation presenting our product.(planned by the end of week 8)
  • Finalized the wiki for judging. (planned by the end of week 8)

Deliverables

At the end of the project we aim to produce the following deliverables:

  • A software model of a biometric scanner that detects suspicious behaviour
  • Full documentation of the development and research process on this wiki
  • A final presentation explaining said model and process
  • A peer review of all group members

USE aspects

User

Primary users

  • Security Guards
  • Police officers
  • Military personnel

Secondary users

  • Persons being filmed

Tertiary users

  • The people manufacturing the product
  • The management responsible for buying the product

User friendliness

Sense of participation

Public survey

In order to gain insight in the current methods of detecting suspicious persons and to look at the wishes of the primary users of the system, a survey will be done with security personnel in airports. The questions we would like to ask are:

  • What do you look for identifying suspicious persons?
  • Do the signs you look depend on the criminal activity?
  • Do you look at body language specifically?
  • Do you rely on facial recognition (wanted list)?
  • Do you look at abnormal movement through a crowd for identifying suspicious persons?
  • What actions do you take after identifying a suspicious person?
  • How often does it occur that an apprehended person turns out innocent? (percentage wise)
  • How many people are present in the departure hall during peak hours?
  • Would you trust a system which detects suspicious persons automatically?
  • How would you prefer the information to be presented to you by the system?
  • What would you like to see in a detection program?

Society

Advantages

Terrorist/criminal activity

Security

Racial/religious tensions

Disadvantages

Privacy concerns

Enterprise

Feasibility

Advantages

Disadvantages

Model

[explanation of concept/pseudocode] [link to actual code?]

Results

References

  1. Jain, A., Bolle, R., & Pankanti, S. (Eds.). (2006). Biometrics: personal identification in networked society (Vol. 479). Springer Science & Business Media.
  2. 2.0 2.1 Junior, J. C. S. J., Musse, S. R., & Jung, C. R. (2010). Crowd analysis using computer vision techniques. IEEE Signal Processing Magazine, 27(5), 66-77.
  3. Cheriyadat, A. M., & Radke, R. J. (2008). Detecting dominant motions in dense crowds. IEEE Journal of Selected Topics in Signal Processing, 2(4), 568-581.
  4. Wang, X., Ma, X., & Grimson, W. E. L. (2009). Unsupervised activity perception in crowded and complicated scenes using hierarchical bayesian models. IEEE Transactions on pattern analysis and machine intelligence, 31(3), 539-555.
  5. Wang, X. (2013). Intelligent multi-camera video surveillance: A review. Pattern recognition letters, 34(1), 3-19.

Minutes

26-04-2017

The subject of the project has been chosen and the deliverables and objectives (as found on the wiki) have been determined.

30-04-2017

  • Orientary research has been performed to develop a better understanding of the subject and better define our goals.
  • A planning and milestones have been determined (see the Approach section)
  • A wiki page has been created, including a template for the documentation with the already available information filled in.