Frequently Asked Questions
Crime Scene Analysis
Crime scene analysis, also known as crime scene reconstruction, involves examining physical evidence and the scene to determine what actions took place during the incident. The analyst then sequences these events.
Crime scene analysis has been an integral part of professional criminal investigations since their inception. Over the past century, numerous authors have addressed this process in criminal investigative literature. In the 1930s, Edward Oscar Heinrich developed a specific theory for crime scene analysis, succinctly stating that “Nothing Just Happens.”
Recurring themes have shaped the discipline of crime scene analysis, establishing a structured approach to its practice. Multiple methodologies exist within the field; BGA utilizes the Event Analysis method. Each methodology is underpinned by fundamental principles, including Steno’s Law of Superposition, Steno’s Law of Lateral Continuity, the concepts of absolute and relative chronology, and Locard’s Principle of Exchange.
Crime scene analysis and behavioral analysis are distinct disciplines. Nonetheless, behavioral analysis incorporates elements of crime scene analysis within its methodology. Criminal profiling, also known as behavioral analysis, seeks to elucidate characteristics of the offender. Analysts are required to assess physical evidence and the crime scene with impartiality and rigor. Thorough and accurate crime scene analysis is essential for effective behavioral analysis.
The process begins with defining specific objective actions at the location of the incident, followed by sequencing those actions. The analyst sets an objective standard to which any theory or statement about the incident may be compared. Investigative, prosecution, and defense theories regarding crime scene facts are evaluated against the analysis. If the evidence does not correspond with the theory, it is necessary to reassess and modify the theory until it accurately reflects the available information. Crime scene analysis can be applied to confirm or dispute testimonial evidence.
Bloodstain Pattern Analysis
Bloodstain pattern analysis (also referred to as blood spatter/splatter analysis) is an in-depth evaluation of the physical bloodstains found in a given scene. This evaluation is directed at three areas, pattern recognition, and classification, the spatial origin or orientation of particular stains and patterns when created (e.g., flows or Area of Origin decisions), as well as aspects of alteration of the stain as a function of environmental exposure (e.g., coagulation times, drying times). The primary focus of the discipline is pattern recognition. Various pattern types are discerned by the analyst based on the physical characteristics present in the unknown scene pattern. The analyst accomplishes this using a criteria-based approach, in which physical characteristics of known pattern types are compared to the unknown scene patterns. To reach this conclusion, the analyst considers a number of factors related to each pattern, including but not limited to number, dispersion, shape, size, volume, orientation, and location. This classification of the pattern (e.g., spurt, cast-off, swipe) defines the basic nature of the physical action that created it. Once this pattern classification is identified, it is then considered in the specific context of that unique crime scene (e.g., consideration of whose blood is present and what injuries or mechanisms were in play in that scene) which ultimately defines the events that occurred or did not occur during the incident.
Blood as fluid is affected as all fluids are by associated physical laws (e.g., the effect of air resistance, gravity, and surface tension). If we expose a mass of blood to a basic event (e.g., striking it, streaming it under pressure), the resulting pattern will demonstrate particular characteristics. Thus bloodstain patterns are reproducible phenomena. Although various classification systems exist to explain the resulting patterns, within all of these systems are basic pattern types. In one form or another, these will include:
- Disruption of blood at a point source (radiating spatter patterns)
Dispersion of blood over time and space from an object in motion (castoff patterns)
Dispersion of blood from a point source as a stream under pressure (projected patterns)
Gravity-induced patterns (drip patterns)
Stains resulting from contact (contact/transfer patterns)
Volume patterns (pools, flows)
The goal of the bloodstain pattern analyst is to recognize the basic nature of the stain through these physical characteristics, properly classify the pattern, and then associate the pattern back to a source event within the context of the scene. This final step is a function of associating the pattern to a specific event that occurred during the incident in question.
For instance: In a scene, we might find a radiating pattern of very fine spatter deposited on a surface in close proximity to a bullet defect. The autopsy information advises us that the victim received a perforating gunshot wound. DNA testing verifies the blood is that of the victim. Using BPA the pattern would be recognized as an impact spatter pattern. The small (sub-millimeter) size of the stains in the pattern might suggest explosive force, and thus the analyst could functionally opine that the pattern was produced by the gunshot event.
No. Bloodstain pattern analysis is class characteristic type evidence. This ability to associate a specific pattern to a specific source event is the goal of BPA, but it is not always feasible. We can generally identify the basic type of pattern, but it is only through scene context that we can ultimately associate it with a specific event. It is not uncommon that the analyst will recognize that a particular type of pattern is present but not be able to limit it to a specific event.
For instance: In a case involving multiple blunt trauma blows delivered by both hands and a weapon, the analyst would certainly recognize the presence of multiple impact spatter patterns. But it is unlikely, based only on the spatter patterns themselves, that the analyst could associate one pattern to a particular blow by a particular weapon.
In BPA there are various systems of classification. Each developed in its own right, and each has value and function. Over time different professional groups and different teachers adopted different systems. Although at first glance, it might seem as if they are disparate systems, as previously discussed, inherent in all of these systems are the basic pattern types. The systems simply start from different initial perspectives. Examples of different classification systems include:
LVIS, MVIS, HVIS. This system concentrates on the idea of spatter size as a principle distinction. Although well known, for various reasons associated with misuse and misunderstanding, this system is being replaced by other classification systems.
Passive/Dynamic. This system is mechanistic and starts with the nature of the underlying event. Dynamic patterns are those associated with disruption mechanisms (e.g., impact, castoff, projected). Passive patterns are contact stains and patterns produced by gravity.
Spatter/Non-Spatter. This system is taxonomic in nature. The principle starting point is whether the pattern is made up of droplets that have been in free flight (small stains circular or elliptical in nature). Spatter groups include impact spatter, arterial spatter, castoff stains, and drips. The non-spatter includes pools, flows, and stains produced by contact.
Bloodstain pattern analysis (BPA) is the scientific study of the physical properties of blood in motion and the static aftermath resulting from the dynamic event(s) involving bloodshed. As an applied science, BPA draws upon the related fields of biology, chemistry, physics, and mathematics. It involves detecting, documenting, describing, analyzing, and evaluating bloodstain pattern(s), specifically the size, shape, distribution, number, and location of bloodstains, as well as the nature of their target surfaces along with their interrelationship(s).
Active areas of research in the field of BPA includes studies of the physical properties of blood, synthetic blood substitutes, the formation of drops by the action of external forces, blood drop behavior in flight through the air, interaction of drops and transferred blood with various surface materials, and blood drying and the appearance of dried stains. In current practical application, BPA is usually applied to observed and documented patterns by applying knowledge obtained through research efforts in determining probable mechanisms of stain or pattern formation.
Different analysts may represent their methodology in different fashions. We describe it as seven steps. Following the scientific method, each step asks and answers specific questions. Of course, the ultimate goal is to try and associate a pattern back to a specific source event. As we teach methodology, these steps include:
Assess and familiarize yourself with the scene.
Identify discrete patterns.
Classify the patterns.
Consider directionality and motion.
Consider points of convergence and area of origin if necessary.
Evaluate interrelationships between patterns and other objects.
Evaluate and identify viable source events, if possible.
“Crime scene reconstruction (CSR) is an important part of forensics that helps effectively establish facts for the court. Shooting Incident Reconstruction (SIR) is a sub-discipline of CSR. Proper training is critical for both practicing analysts and those interested in entering the field of forensics. At Bevel, Gardner and Associates, we offer Shooting Incident Reconstruction training, as well as other courses in forensics, to further your knowledge and prepare for a career in the field of forensics.