Tag Archives: motorcycle accident expert

Motorcycle accident expert Dr. John Lloyd has served attorneys nationwide for 25+ years in biomechanics, human factors, helmet testing and motorcycle accident expert

Scientific Articles

Biomechanics

Admissibility of Biomechanics Testimony on the Causation of Injury

Forensic Biomechanics – The Science of Injury Causation

Motorcycle Accidents

Biomechanics of Solo Motorcycle Accidents

Conspicuity of Motorcycles and Riders

Left Turn Across Motorcycle Path

Solo Motorcycle Crashes

Motorcycle Helmets

Biomechanical Evaluation of Motorcycle Helmets: Protection Against Head & Brain Injuries

What Every Rider Needs to Know About Motorcycle Helmets

Crash-Related Motorcycle Helmet Retention System Failures

Helmets – The Ultimate Protection?

Helmets Do Not Prevent Brain Injury

Motorcycle Helmets Provide Inadequate Protection Against Traumatic Brain Injury

Sport and Football Helmets

Brain Injury in Sports

How Well Do Football Helmets Protect Against Concussion and Brain Injury?

Researchers Discover Objective Indicator of Concussion

New Helmet Technology Reduces Brain Injuries

Truck Accident Reconstruction, Injury Biomechanics and Human Factors

Accidents involving commercial vehicles and truck accident typically involve extensive damage and more severe injuries to vehicle occupants due to the magnitude of forces involved.

Lloyd truck accident injury biomechanics human factors expert

Truck Accident Statistics

  • According to Federal Motor Carrier Safety Administration (FMCSA) data, one person is injured or killed in a truck accident every 10 minutes.
  • In 2014 there were 213,000 trucking accident resulting in property damage only, 52,000 injury-causing accidents, and 1885 fatal crashes.
  • About half of all tractor-trailer accidents involve front-end collisions. Back end and side collisions occur in 15 and 12 percent of all crashes, respectively
  • The top 5 states in which fatal truck accidents occur include Texas, California, Florida, Pennsylvania and Georgia.

Exposure

According to a 2016 AAA report, passenger car drivers spend about 290 hours on the road and travel an average of 10,900 miles each year, with atypical life of a passenger car of 8 years and 150,000 miles. Whereas, tractor-trailer operators may work up to 70 hours per week (55 hours driving time) and often travel 10,000 miles or more in a month. Tractors are typically kept in service for 6 years, during which time they can travel 600,000 miles or more. So, mile-for-mile, a tractor-trailer operator’s exposure is 10-fold that of a passenger car driver.

Who’s at fault?

Nearly 90 percent of all trucking accidents result from human error, rather than mechanical breakdown, equipment failure, bad weather or poor road conditions. Examples of human carelessness or recklessness responsible for causing truck crashes include:

  • Driving while under the influence of drugs or alcohol
  • Distracted driving — eating, using cell phones, applying makeup
  • Driver fatigue
  • Running red lights, speeding, failing to yield or otherwise violating traffic laws

While some accidents may involve human error on the part of the tractor-trailer operator, trucks and truck drivers are typically held to a higher standard of operation by Federal Laws and Regulations than passenger cars and drivers. Truck drivers need to successfully complete a more extensive driver training program than is required to drive a passenger car. Commercial vehicles are also inspected more thoroughly and on a more frequent basis.

In fact, more than 75% of truck driving accidents are caused by the driver of the passenger vehicle.

Truck Accident Expert

Dr. Lloyd has served as an expert for both defense and plaintiff’s counsel on a number of cases nationwide involving trucking accidents. Dr. Lloyd is uniquely qualified in that he is certified in accident reconstruction, is an internationally-recognized expert in injury biomechanics and can also address the unique human factors issues that affect tractor-trailer operators, such as visual perception and perceived reaction time.

Please call Dr. Lloyd at 813-624-8986 or email DrJohnLloyd@Tampabay.RR.com to discuss how he can be of assistance with your case.

Motorcycle Accident Expert

Dr. John Lloyd has over 30 years of forensic consulting experience as a motorcycle accident expert including motorcycle handling and operation as well as maintenance, repair and motorcycle inspection.

motorcycle accident expert - Dr John Lloyd

Education

B.Sc.(Hons) (Ergonomics / Human Factors), Loughborough University, UK. 1992
PhD (Ergonomics / Biomechanics), Loughborough University, UK. 2002

Motorcycle Endorsement

1993 to current date

Memberships

  • Gold Wing Road Riders Association (former)
    • FL1-A chapter member
    • Road Captain
  • BMW Motorcycle Owners of America
  • BMW Riders of Tampa Bay
  • American Motorcycle Association
  • ABATE of Florida

Motorcycles Owned

  • Honda Rebel 250
  • Honda Shadow VLX600
  • Honda Shadow VT700
  • Honda Magna VF750
  • Honda Shadow VT1100
  • Honda Gold Wing GL1200
  • Honda Gold Wing GL1500
  • BMW K1200LT
  • Yamaha FZ1
  • Kawasaki Vulcan Nomad 1600
  • BMW R1200RT
  • Honda CBR929RR
  • Yamaha Super Tenere
  • Harley Davidson FLHTK Ultra Limited
  • BMW R1250RT

Advanced Rider Training

  • Motorcycle Safety Foundation (MSF) Experienced Rider Course
  • Motorcycle Safety Foundation (MSF) Advanced Rider Course
  • Total Rider Tech (Lee Parks)
  • Advanced Ride Like a Pro Course
  • RideSmart (Tampa PD)
  • ChampStreet (YCRS)

Professional Memberships

  • Accreditation Commission for Traffic Accident Reconstructionists (ACTAR)
  • National Association of Traffic Accident Reconstructionists and Investigators
  • National Association of Professional Accident Reconstruction Specialists (NAPARS)
  • Society of Accident Reconstructionists
  • State Rider Safety Association (SRSA)

Motorcycle Accident Expert Training

  • EDC Accident Reconstruction Course – HVE EDCRASH / EDSMAC, Miami, FL
  • Certification in Reconstruction and Analysis of Motorcycle Accidents – SAE International, Detroit, MI
  • Certification in Investigation of Motorcycle Crashes – Institute for Police Training and Management (IPTM), Jacksonville, FL.

Other relevant Professional Training

  • LabView Introductory and Advanced workshops, National Instruments
  • Successful Measurement of Dynamic Force, Pressure, and Acceleration, presented by PCB Piezotronics
  • Using Mimics to create 3D Finite Element models from Radiographic CT and MR images, presented by Materialize
  • Matlab fundamentals, presented by The Mathworks

Please call Dr. Lloyd at 813-624-8986 or email DrJohnLloyd@Tampabay.RR.com to discuss how he can be of help to you with your case.

Solo Motorcycle Crashes

A solo motorcycle crash is one of the leading causes of motorcycle accidents. These accidents are unique in that, typically, no other vehicles are involved. Oftentimes the root cause is rider error due to the fact that motorcycles are considerable more complex to operate than passenger vehicles. Discover how to avoid solo motorcycle crashes with valuable insights from a motorcycle expert.

Riders involved in a solo motorcycle crash typically fit one of two categories:

  1. Riding too fast
  2. Inadequate experience

The first category speaks for itself. Riding too fast for conditions reduces time and distance available to respond safely to potential hazards, such as other roadway users.

Lack of experience includes lack of appropriate training or failure to maintain training. Many riders purchase an expensive motorcycle – far too powerful and heavy for their riding abilities – and ride less than 3000 miles per year – generally in a straight line. When they are faced with a hazard, they panic and make poor choices, all too often resulting in injury or death.

Motorcycle Braking

Unlike cars, the front and rear brake systems on a motorcycle are typically independent — the front brake is operated by a lever on the right side of the handlebar, while the rear brake is operated by a foot pedal, also on the right side. As car drivers we learn that hard braking is performed by the right foot. However, doing so on a motorcycle will inevitably lead to trouble. In fact, about 70 percent of the braking power on a motorcycle comes from the front brake lever.

As front brake force increases weight transfers to the front tire, increasing the tire force acting on the road surface, which permits application of even greater front brake force.

solo motorcycle crash - efficient braking - insights from motorcycle crash expert

However, sudden over-braking on the front, on a motorcycle not equipped with ABS, can produce a front-tire skid, which can cause loss of control in under one second. So, for an inexperienced rider it can be challenging to find the ‘sweet-spot’ between hard braking and over-braking on the front tire.

solo motorcycle crash - rear brake skid - insights from motorcycle crash expert

Whereas, utilization of the rear brake without the front brake produces only 30% braking efficiency and can cause the rear end of the motorcycle to skid and ‘fishtail’, due to the fact that there is generally less weight and a larger contact area (less pressure) on the rear tire.

Experienced motorcyclists learn to use both the front and rear brakes in unison and, together both brakes can out-perform the stopping power of most other roadway vehicles.

Motorcycle Steering

Motorcycles also differ from other vehicles in the way that they steer. In a car if you want to go right you turn the steering wheel to the right and visa versa. Whereas, on a motorcycle if you want to go right you turn the handlebar to the left. On the surface this appears to be counter-intuitive. However, due to the geometry of motorcycles, when you turn the handlebar in one direction, the bike will lean in the opposite direction. It is this lean that causes the motorcycle to turn. This phenomenon is called counter-steering.

solo motorcycle crash - counter steering - - insights from motorcycle crash expert

To turn a tighter curve you simply increase the lean angle. Modern sport motorcycles are capable of lean angles up to 60 degrees, allowing motorcycle racers to turn corners at high speeds. However, most curves on public roads don’t require more than 15 degree lean angle, which is generally the comfort limit of many novice riders.

Motorcycle Crash Expert

Please call Dr. Lloyd at 813-624-8986 or email John@DrBiomechanics.com to discuss how he can be of help to you with your case.

Human Factors

Human Factors Engineering (aka Ergonomics) is the science of work, derived from the Greek ergon (work) and nomos (laws) .  Human Factors is a systems-oriented discipline which extends across all aspects of human activity, drawing on a number of scientific disciplines, including physiology, biomechanics, psychology, anthropometry, industrial hygiene, and kinesiology (U.S. Dept. of Labor, 2000)

  • Physical ergonomics is concerned with human anatomical, anthropometric, physiological and biomechanical characteristics as they relate to physical activity.
  • Cognitive ergonomics is concerned with mental processes, such as perception, memory, reasoning, and motor response, as they affect interactions among humans and other elements of a system.

human factors

Dr. John Lloyd attended Loughborough University in England, where he attained a BSc. with Honors in Ergonomics (1992) and Ph.D. in Ergonomics (2002). Loughborough University is considered a premier academic institute for the study of Ergonomics / Human Factors and is currently ranked #4 University in the UK, behind Oxford and Cambridge.

In addition, Dr. Lloyd has held the distinction of Board Certification since 1995 and is a member of the Human Factors and Ergonomics Society as well as the American Society of Biomechanics.

Dr. Lloyd has been accepted by the courts in Florida and other states as an expert in Human Factors and has provided testimony on:

Conspicuity of Motorcycles and Rider Visibility

John Lloyd, PhD, CPE, ACTAR

The number one cause of motorcycle crashes involving other vehicles is a left-turning driver across the rider’s path. In every case, the intruding motorist explains that they “did not see the approaching motorcycle”. The motorcycle was not conspicuous.

John Lloyd motorcycle crash expert

Expectancy

How can a motorist fail to see something as large as a modern motorcycle? The answer – expectancy. According to the National Highway Transportation Safety Authority (NHTSA), motorcycles account for only 0.6% of total vehicle miles traveled in the United States. Thus, motorists have more than a 99% expectancy that the next vehicle they see will NOT be a motorcycle. Through experiential learning drivers have learned to look for other automobiles, not motorcycles.

It is not that a motorist does not see the motorcycle. However, it does not meet their expectation and therefore they may fail to identify the approaching motorcycle. 

What can motorcyclists do to reduce their risk of collision when a driver causes a path obstruction at an intersection? According to human factors research, roadway users respond to hazards based on available information. They fail to respond when the available information is insufficient. Based on my experience as a motorcycle rider and human factor expert, conspicuity is key to increasing the information available to motorists. As motorcyclists we need to take responsibility to make our presence known to other roadway users. 

Many opportunities to improve conspicuity are available, which generally fall into two categories – audible and visual. Many riders are familiar with the concept “Loud pipes save lives”, as often declared on stickers affixed to their helmets. However, since noise intensity decreases as a function of the distance-squared, loud pipes are only effective in close proximity. Moreover, the greater volume is actually behind the motorcycle, not in front.

Human Factors research teaches that to improve driver detection and therefore avoidance of motorcycles on the road, we can enhance our visual conspicuity by following a few simple guidelines. These are captured by the acronym CAPLETS, which includes Contrast, Anticipation, Pattern, Lighting, Eccentricity, Time of Exposure, and Size.

Conspicuous Contrast

conspicuity contract hi vis motorcycle helmet jacket

Contrast addresses the ability of a motorcycle and rider to stand out from their environment. For example, a black motorcycle on an asphalt surface is more difficult to distinguish than a yellow or red bike, especially under nighttime conditions. The same is true for the rider. Dark clothing makes it more difficult for a motorcyclist to be detected on the roadway. Brighter colors, especially high-vis yellow or orange, are more likely to create a greater contrast and therefore be more recognizable. 

Anticipation Conspicuity

Anticipation refers to the expectation of a given event. When motorcyclists ride together in a group, motorists are more likely to expect and therefore look for additional motorcycles. For this reason, a group riding together is often safer than a solo motorcyclist traveling alone.

Conspicuous Patterns

Patterns aid recognition by relying on one’s past experiences. Obviously, most motorists are familiar with the shape or pattern of a motorcycle and can easily distinguish one during daytime conditions. However, at night the pattern exhibited by a single headlight, may not aid a driver in identifying an approaching motorcycle. Motorcycles equipped with additional lighting that outlines its shape are more likely to be recognized on the roadway and hence less likely that their path will be intruded by a motorist.

Conspicuous Lighting

The purpose of Lighting is somewhat self-explanatory. More lighting means more information for other roadway users. Lighting is beneficial not just at night, but also during the day. The photograph, below, of one of my motorcycles illustrates how effective additional lighting is in providing information necessary to motorists to recognize my presence on a motorcycle. Headlight modulators can also increase conspicuity by switching between low and high beam automatically at a rate of approximately 4 times per second. The modulators are equipped with a light sensor, which turns off this feature at night. I have personally installed headlight modulators on several of my bikes and can attest as to their effectiveness.

conspicuity conspicuous motorcycle lights lighting

Eccentricity

Eccentricity relates to the viewing angle. When a motorcycle is approaching an intersection, the viewing angle of the rider to an automobile on the right, waiting to make a left turn across the roadway is close to zero. Whereas, for the driver at the road junction, their viewing angle, unless properly turning their head to look for oncoming vehicles, is close to 90 degrees. There is not much that a rider can do to improve the motorists viewing angle. However, I have found that, when approaching an intersection at which a driver is waiting to make a turn across my path, by moving my motorcycle side to side within my lane helps to catch their attention. 

Time of Exposure

Time of Exposure. It is critically important at intersections to ensure that no visual obstructions exist between the rider and motorist that could limit time available to detect your presence. If fixed obstructions, such as trees or signage, are present I will position my motorcycle in a manner that provides a clear line of sight. Whereas, if a vehicle in front of or to the right of my motorcycle may pose a potential visual obstruction at an approaching intersection, I will move forward, or drop back, allowing a clear 3-second window between myself and other vehicles, thereby affording a waiting motorist every opportunity to detect and identify me on the road. Speed can also negatively affect time of exposure. At greater speeds other drivers have less available time to detect a motorcyclists presence. For this reason, I advise that it is best to travel at or within 5 mph of the posted speed limit. 

Conspicuous Size

Size matters, when it comes to conspicuity. Remember that motorists are looking for other automobiles. Larger motorcycles tend to be identified more quickly than smaller bikes, or bicycles. An opportunity may exist to make your motorcycle appear larger than reality through the use of additional lighting, such as led lights mounted on left and right side mirrors, and/or by the front wheel axle. 

Please call Dr. Lloyd at 813-624-8986 or email DrJohnLloyd@Tampabay.RR.com to discuss how he can be of help to you with your case.

Motorcycle Pothole Crash

Motorcycles are highly sensitive to changes in roadway conditions. Potholes can destabilize a motorcycle, causing the rider to lose control. The following is a case in which a rider claimed he was traveling at only 15 miles per hour, when he came upon a large pothole in the roadway and lost control. The motorcycle fell to the right, with the right foot peg penetrating the rider’s leg, leading to a near amputation of his right foot. Dr. Lloyd was retained to investigate the cause of the motorcycle pothole crash.

Test Instrumentation

An exemplar Honda CBR 929RR motorcycle was acquired and instrumented with accelerometers installed on the front axle, rear axle and handlebars:

motorcycle pothole crash sensors

Data acquisition was controlled using a National Instruments cDAQ 9178 and acquired at 10 kHz per channel on a Windows tablet running LabVIEW software:

motorcycle pothole crash data collection

Pothole Crash Testing

Using the instrumented motorcycle, Dr. Lloyd constructed an exemplar pothole in an open parking lot using ramps to investigate how the length and depth of the pothole affected stability of the motorcycle. In addition to sensors, testing was recorded using high speed and standard video, as well as GoPro cameras mounted on the motorcycle

motorcycle pothole crash testing

Results

Based on analyses and physical evidence, that the speed of the motorcycle while crossing the roadway defect was likely 14 -18 miles per hour. At such speeds, the front and rear suspensions have a tendency to approach maximum compression. along with substantial deformation of the tires.

Conclusions

Dr. Lloyd determined that the motorcycle crash was caused due to the motorcycle accelerating as it crossed the pothole. When the rear wheel crossed the fore edge of the defect it lost contact with the roadway and the rear wheel speed increased without resistance. Upon contact with the aft edge of the roadway defect the rear wheel was at a higher rate of speed than the rest of the motorcycle, causing the motorcycle to unexpectedly wheelie.

motorcycle pothole crash video

Please call Dr. Lloyd at 813-624-8986 or email DrJohnLloyd@Tampabay.RR.com to discuss how he can be of help to you with your case.

Left Turn Across Motorcycle Path

In 2016 there were more than 8.4 million motorcycles registered in the United States, representing 3.2% of all US vehicles. California, Florida and Texas were the leading States in terms of the motorcycle popularity; collectively representing 22% of all US registered motorcycles. According to the U.S. National Highway Traffic Safety Administration (NHTSA), when compared per vehicle mile traveled with automobiles, due to their vulnerability, motorcyclists’ risk of a fatal crash is 30-35 times greater than that of a car occupant.

Number One Cause of Motorcycle Crashes

Seventy-five percent of accidents were found to involve a motorcycle and a passenger vehicle, while the remaining 25% of accidents were single motorcycle accidents.

The number one cause of motorcycle crashes is a motorist making a left turn across motorcycle path. With reference to the Hurt report in the United States and the MAIDS in-depth investigation of motorcycle accidents in Europe, approximately two-thirds of all motorcycle crashes involving other vehicles are caused due to violation of the motorcycle rider’s right of way by the failure of motorists to detect and recognize motorcycles on the road. 

left turn across the path of an oncoming motorcycle

While the motorcycle rider has right of way, they are also more vulnerable to injury. Motorcyclists must therefore be extra-vigilant, especially when approaching intersections. Appropriate riding gear, including a DOT certified helmet, motorcycle jacket and riding boots offer the motorcyclist the best protection. Findings of the Hurt study indicate that severity of motorcyclist injury increases with speed, alcohol consumption, motorcycle size and speed.

Motorcyclist Conspicuity

Conspicuity is one of the key factors in motorcycle road crashes around the world. The inability and difficulty of other road users in detecting motorcycles either at day or at night has contributed to conspicuity related motorcycle crashes. Additional lights and brightly colored riding gear can help to improve motorcyclists conspicuity to other roadway users. The following image depicts this author wearing a hi-visibility motorcycle jacket and helmet to enhance conspicuity.

Please call Dr. Lloyd at 813-624-8986 or email DrJohnLloyd@Tampabay.RR.com to discuss how he can be of help to you with your case.

Biomechanics of Solo Motorcycle Accidents

The following is a peer-reviewed article on Motorcycle Accident Reconstruction, which was originally published in the Journal of Forensic Biomechanics in January 2016.

Corresponding author: John D Lloyd, Research Director, BRAINS, Inc., 32824 Michigan Avenue San Antonio, Florida, 33576, USA, Tel: 813-624-8986; Fax: 352-588-0688; E-mail: drjohnlloyd@tampabay.rr.com

  1. Abstract

In a motorcycle accident, the motorcycle and rider typically become independent, each following their own path to final rest. Consequently, the biomechanical analysis of a motorcycle accident reconstruction is complex. A biomechanical model to assess rider kinematics associated with motorcycle accidents is presented, which may be important to forensic scientists involved in the analysis of such events. This model can also be applied to other activities, including cycling, equestrian sports, skiing, skating, running, etc.

In a motorcycle accident reconstruction, it is first important to understand the mechanisms by which a rider may be ejected from their motorcycle and how drag factors affect the motorcycle and rider independently. Next we determine rider trajectory, taking into consideration rider anthropometry and posture, results from which are used to derive impact velocity as a function of linear and angular components. A case study is presented, demonstrating how the presented model can be applied to a collision involving a single motorcycle.

  1. Keywords:

    Forensic science; Biomechanics; Kinematics; Anthropometry; Motorcycle accident reconstruction

  2. Introduction to Motorcycle Accident Reconstruction

Motorcycles are a luxury in the developed world, where they are used mostly for recreation. Whereas in developing countries, motorcycles are required for utilitarian purposes due to lower prices and greater fuel economy. It is estimated that in 2016 there will be more than 134 million motorcycles worldwide [1], 60-80% of which are in the Asia Pacific and Southern and Eastern Asia regions. In 2011 there were more than 8.2 million registered motorcycles in the United States [2], representing 3% of all US registered vehicles, with California, Florida and Texas leading the number of motorcycles per state [3].

3.1. Epidemiology of motorcycle accidents

In the United States motorcyclists travelled 18.5 billion miles in 2011, which represents only 0.6% of total vehicle miles travelled, yet motorcyclists accounted for 14% (4,612) of traffic fatalities and 4% (81,000) of all occupant injuries [2]. According to the U.S. National Highway Traffic Safety Administration (NHTSA), when compared with automobiles, per vehicle mile traveled, motorcyclists’ risk of a fatal crash is 35 times greater than that of a car occupant [4].

Two major epidemiologic studies into the causation of motorcycle accidents have been conducted in North America and Europe: the Hurt Report and the MAIDS report. The Hurt Report [5] showed that failure of motorists to detect and recognize motorcycles in traffic is the prevailing cause of motorcycle accidents. Seventy-five percent of accidents were found to involve a motorcycle and a passenger vehicle, while the remaining 25% of accidents were single motorcycle accidents. Two-thirds of motorcycle-car crashes occurred when the car driver failed to see the approaching motorcycle and violated the rider’s right-of-way. Findings of the Hurt study indicate that severity of motorcyclist injury increase with speed, alcohol consumption, motorcycle size and speed.

The MAIDS study (Motorcycle Accidents In Depth Study) [6] is the most recent epidemiologic study of accidents involving motorcycles, scooters and mopeds, which was conducted in 1999 across five European countries to investigate motorcycle accident exposure data. Key findings show that passenger cars were the most frequent collision partner (60%), where 69% of the drivers report that they did not see the motorcycle and the predominance of motorcycle accidents (54.3%) occurred at an intersection.

In the United States alone, it is estimated that the total direct costs associated with motorcycle crashes in 2010 was approximately $16 billion. However, the US Government Accountability Office (GAO) predicts that full costs of motorcycle crashes are likely considerably higher because some difficult-to-measure costs, such as longer-term medical costs, are not included [7].

  1. Biomechanical Model

A new model is presented for the purpose of investigating motorcycle accident reconstruction biomechanics involving a lone motorcycle, which accounts for 25% of all motorcycle-related accidents according to the Hurt report [5]. This model is unique in that it incorporates measures of rider anthropometry (body measurements) and riding posture, which have a direct effect on trajectory and overall height of the vertical component of the impact.

The model presented herein may be applied not only to motorcycle accidents, but also to a wide range of activities, including cycling, equestrian sports, skiing, skating, running, etc.

  1. Methods

It is first important to understand the mechanisms by which a rider may be ejected from their motorcycle and how drag factors affect the motorcycle and rider independently. Next we determine rider trajectory, results from which are used to derive impact velocity as a function of linear and angular components. Finally, characteristics of the impact surface are considered with respect to impact accelerations.

5.1. Rider ejection

There are a number of ways that a rider can be ejected from the bike in a lone motorcycle accident. Two common ways of ejection are the lowside (Figure 1A) and highside (Figure 1B) crash. A rider may also be ejected over the handlebars (Figure 1C).

Figure 1 – Rider Ejected from Motorcycle

Rider Ejected from Motorcycle - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

The lowsider or lowside is a type of motorcycle crash usually occurring in a turn (Figure 1A). A lowside crash is caused when either the front or rear wheel slides out as a result of either too much braking in a corner, too much acceleration through or out of a corner, or too much speed carried into or through a corner for the available traction. A lowside crash may also be caused by unexpected slippery or loose material (such as oil, water, dirt or gravel) on the road surface.

A highsider or highside is a type of motorcycle accident characterized by sudden and violent rotation of the motorcycle about its longitudinal axis. This generally happens when the rear wheel loses traction, skids, and then suddenly regains traction, creating a large torque, ejecting the rider off the side of the motorcycle, oftentimes head-first (Figure 1B).

Highside and lowside accidents differ as follows: during a lowside the rear wheel slips laterally and continuously until the motorcycle falls onto the side facing the inside of the corner.Whereas during a highside crash the rear wheel slips laterally before suddenly regaining traction and flipping the motorcycle toward the outside of the corner (the higher side of the motorcycle). Highsides happen quickly and are very violent consequently injuries tend to be more severe in a high side crash, compared to a lowside crash.

Endo, short for “end over end,” occurs when the front end of a motorcycle stays fixed while the rear rotates up into the air, causing a rider to fly over the handlebars (Figure 1C).

5.2. Drag factors

Drag factors for motorcycles have been established based on motorcycle accident reconstruction and typically range from 0.2-1.0 [8], where 0.25 represents a motorcycle with a fairing [9], such as a sport motorcycle. Sport and sport touring motorcycles will likely slide further than a cruiser-style motorcycle, which have more external components that resist sliding, for which a drag factor of 0.5 is commonly adopted Table 1, below, presents drag factors for street motorcycles sliding on typical road surfaces [10-13].

Table 1: Drag Factors for Sliding Motorcycles

Drag Factors for Sliding Motorcycles - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

Drag factors for the rider are typically higher than those for motorcycles sliding on a dry asphalt or concrete roadway. An extensive series of motorcycle accident reconstruction tests were carried out by the West Midlands Police in the United Kingdom in which they calculated the drag factor value of a crash-test dummy sliding across an airfield surface. The resulting coefficient was found to vary between 0.57 and 0.85 for normal clothing [14].With similar drag factors for dry and wet roadway conditions [15]. For the purpose of accident reconstruction, a drag factor of 0.7 for a clothed individual sliding on a roadway is generally accepted.

Evidence from final rest positions of the motorcycle and rider can be used to establish whether the rider was involved in a lowside or highside motorcycle ejection. In a lowside crash the motorcycle will tend to slide further than the rider. Whereas in a highside crash, the rider is ejected from the motorcycle, traveling additional distance over ground in a similar direction to the motorcycle, prior to making contact with the ground and initiating the slide. Hence, in a highside crash, the final rest position of the rider may be beyond the final rest position of the motorcycle. Furthermore, in higher-energy ejection crashes the rider is more likely to both slide and tumble, resulting in a longer travel distance from location of ejection from the motorcycle, as well as additional injuries as evidenced by fractures, lacerations and contusions to various regions of the body.

5.3. Rider anthropometry

Anthropometry is the study of human body measurements. Rider anthropometry will directly affect fall height, since head center of mass (HCOM) and overall center of mass (RCOM) varies between individuals.

In a lowside crash, seated height of the center of mass (HCOM) of the rider’s head approximates vertical fall height. Whereas in a highside crash vertical fall height is a function of seated head CoM height (HCOM), plus additional height gained based on trajectory of the rider calculated with reference to overall center of mass of the rider (RCOM) (Figure 2).

Figure 2 – Fall Height Associated with Low side and High side Accidents

Fall Height Associated with Low side and High side Accidents - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.4. Rider center of mass

Rider center of mass height (RCOM) is located anatomically with respect to the second sacral vertebra (S2), which can be visually estimated as approximate in height to the omphalion (navel), and is measured vertically with respect to the road surface. The preferred method for determining RCOM is to measure seated height of the rider on the subject motorcycle (Figure 3). If the rider is not available due to injury or fatality, then an exemplar same-gender person of similar height and weight may be used. If the subject motorcycle is not available due to extent of damage, then an exemplar motorcycle should be obtained. With the motorcycle supported perpendicular to the road by an assistant (not on side stand or center stand), and rider’s hands on the handlebar grips and feet on the foot pegs, measure the vertical height from the ground to the motorcycle seat at the location of the ischial tuberosities (base of the pelvic bones at the seat surface). An anthropometer and spirit level should ideally be used for accuracy and measurements recorded in millimeters to maximize precision.

Figure 3 – Rider anthropometry

Rider Anthropometry - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

As an alternative method, rider seated height can be calculated by sourcing motorcycle seat height, from manufacturer specifications, from which a correction factor for suspension compression under mass of the rider is subtracted. Suspension compression, also known as sag, will vary by motorcycle type and mass of the rider. A general rule of thumb is that the front sag should be about 30-35% of travel, while the rear should be at about 25%, which equates to 30-40 mm at the front and 25-35 mm at the rear for most bikes [16]. Therefore, a reasonable correction factor for suspension sag is 30-35 mm.

For both methods, an adjustment must be added to the compressed seat height to determine RCOM. According to Pheasant [17], seated RCOM is equal to seat height plus 10% of total stature (standing height). This factor calculation is identical for both males and females (Table 2).

Table 2: Anthropometric Data

Anthropometry - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.5. Head center of mass

Head center of mass (HCOM) height can also be measured directly using the method described earlier, with the rider seated on the subject motorcycle in the correct riding position. An anthropometer is used to measure the vertical height from the ground. If the rider and/or subject motorcycle is unavailable, a substitute individual of similar height and weight and exemplar motorcycle may be used. The canthus (outer corner of the eye) is used as an anatomical landmark reference, equal in height to the center of mass of the head (Figure 3).

Alternatively, seated head center of mass (HCOM) can be calculated as a function of stature (standing height). Utilizing data from the 1988 Anthropometric Survey of U.S. Personnel [18], HCOM is derived by multiplying stature by 45.2%. Similar to the RCOM calculation, HCOM must be corrected for posture by multiplying HCOM by the cosine of seated back angle (β), measured with respect to the vertical axis.

5.6. Trajectory of the rider

The trajectory is the path that a rider is thrown or vaulted under the action of gravity, neglecting all other forces, such as friction from air resistance, without additional propulsion (Figure 4) and is defined by Equation 1.

Equation 1 – Trajectory of the ejected rider (y)Equation Trajectory of the Ejected Rider - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

Figure 4 – Trajectory of an Ejected Rider

Trajectory of an Ejected Rider - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

The following standard mathematical formulae are used to determine specific components of trajectory that are pertinent to the kinematic analysis of a rider ejected from a motorcycle.

5.7. Distance travelled

In a motorcycle accident reconstruction it may be possible to establish the actual distance of ejected travel of the rider, based upon location of ejection, typically between the end of any tire skid marks and start of gouge marks on the roadway, and location of bodily impact with the ground, identified by helmet paint transfer and/or identification of clothing fibers or body tissue on the roadway consistent with the rider. If the speed of the motorcycle at ejection (νejection) is also known, then the distance travelled (d) can be computed using the formula below, taking into account any correction factors for relative change in road height from location of ejection to impact.

Equation 2 – Horizontal distance traveled (d):Equation Horizontal Distance Travelled - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

However, the location of bodily impact is often difficult to identify, in which case reasonable assumptions may be made, including utilization of an estimated ejection angle (θ).

5.8. Maximum height

One of the most critical factors for determination of total impact velocity in a motorcycle accident reconstruction is the maximum height attained by an ejected rider, which is calculated according to

Equation 3 – Maximum height (h):Equation Maximum height - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.9. Ejection angle

The ejection angle (θ) is the angle at which a rider must be launched in order to travel a certain distance, given the initial velocity. Oftentimes, based on the final rest positions of the motorcycle and rider and in consideration of appropriate drag factors, it is possible to approximate rider ejection velocity. Air resistance is considered negligible, therefore angle and velocity at ejection are considered equal to the angle and velocity at impact.

Equation 4 – Ejection angle (θ):Equation Ejection Angle - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.10. Rider impact velocity

Total impact velocity is derived on the basis of its vertical, angular and travel velocity components.

5.11. Linear vertical impact velocity

Vertical impact velocity is computed as a function of seated head height, plus any additional height gained due to rider ejection from the motorcycle. The potential energy (P.E.) at any point will depend on the mass (m) at that point and its distance above the ground (h), multiplied by the gravitational acceleration constant (g) (Figure 5).

Figure 5 – Potential Energy of a Motorcyclist

Potential Energy of a Motorcyclist - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

The potential energy of the entire system is the integral of the energies of each finite mass element of the motorcycle plus rider over its height: . For simplification, we assume that the mass is evenly distributed over the system. Hence, P.E=m g h.

In physics, the law of conservation of energy governs that energy can neither be created nor destroyed, Potential Energy (P.E.) at the start of a fall must be equal to the Kinetic Energy (K.E.) at the end of the fall, which is expressed as the product of one half mass (½m) and impact velocity squared (v2). Therefore P.E. = K.E. = ½ mv2, Solving for linear impact velocity gives Equation 5:

Equation 5 – Linear impact velocity:   

Equation Linear Impact Velocity - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd5.12. Angular vertical impact velocity

In real-world scenarios a falling rider will not follow a purely linear path [19], especially when coupled to a rigid body such as a motorcycle, hence angular velocity will also be generated (Figure 6).

Figure 6 – Falling Motorcyclist

Falling Motorcyclist - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

If a motorcyclist falls from a vertical to a horizontal position, we can assume that Potential Energy (P.E.) is converted to rotation: 1/2 m g h = ½ I ω2 where is the Moment of inertia, defined as the ratio of the angular momentum (L) of a system to its angular velocity (ω) around an axis: I=L/w which may also be expressed in terms of its mass (m) and its distance (r) from the pivot point as: I=mr2. Since r = h, the equation can be rewritten: mgh=1/2mh2w2. Instantaneous angular velocity at impact can be expressed in terms of linear components: ν = ω h, thus mgh=1/2mvwhich yields Equation 6:

Equation 6 – Instantaneous velocity due to angular rotation upon impact:Equation Instantaneous velocity due to angular rotation upon impact - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

Hence total impact velocity is the sum of its linear and angular components.

Therefore, the sum of impact velocity due to linear and angular components is greater than impact velocity due to linear components only and is expressed as:

Equation 7 – Impact velocity:

Equation Impact Velocity - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd 5.13. Travel impact velocity

As previously stated, air resistance during a short fall is considered negligible, therefore angle and velocity at ejection (α, νejection) is considered equal to the angle and velocity at impact. Velocity due to ejection can be expressed in terms of its vertical and horizontal components . Assuming that ejection angle is measured with reference to the horizontal axis, then:
Equation 8a – Vertical ejection velocity:  Equation Vertical Ejection Velocity - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd, and Equation 8b – Horizontal ejection velocity:Equation Horizontal Ejection Velocity - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.14. Impact velocity vector

The impact velocity vector has both vertical and horizontal components. The total vertical velocity is the sum of the linear and angular velocity components, plus the vertical components of velocity due to ejection. The total horizontal velocity will equal the horizontal component of velocity due to ejection. The magnitude of the impact velocity vector will be the square root of the sum of its vertical and horizontal components, hence:

Equation 9 – Impact velocity vector:Equation Impact Velocity Vector - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

and the effective angle of the impact velocity vector relative to the vertical axis is determined as:

Equation 10: Effective impact angle:Equation Effective Impact Angle - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

5.15. Impact acceleration

In a motorcycle accident reconstruction, impact acceleration is determined as a function of rate of change of impact velocity over time (t): , where the duration of the impact will be directly affected by the stopping distance of the impacted material. Roadside materials, such as grass or dirt inherently have larger stopping distances than typical roadway materials, such as asphalt or concrete. Hence, the impact accelerations experienced by a rider landing on a grassy area will be considerably less than if they impacted the roadway.

  1. Motorcycle Accident Reconstruction Case Study

A cruiser motorcycle was traveling along a divided highway, approaching an intersection, when a slow-moving automobile made an abrupt unanticipated lane change immediately in front of the motorcycle. The rider applied the brakes, locking up the rear wheel, causing the motorcycle to skid. The motorcyclist swerved in an attempt to avoid contact with the automobile. The left motorcycle footplate struck the rear corner of the automobile at an impact speed of 7.2 m/s (16 mph), causing the motorcycle to rotate violently about its long axis until the tires gained traction and the rider was thrown from the motorcycle. The final resting position of the rider was 4.6 m (15 ft.) past the final resting position of the motorcycle, to which the rider slid approximately 3.7 m (12 ft.) after being vaulted approximately 6.1 m (20 ft.) from the motorcycle (Figure 7).

Figure 7 – Case study: Automobile Avoidance Collision

Case study- Automobile Avoidance Collision - Motorcycle Accident Reconstruction Expert Witness | Dr John Lloyd

The rider center of mass was calculated based on anthropometric derivation from known standing height of 1.7 m (5’8”) and manufacturer’s seat height specification of 0.7 m (27.5”), from which a suspension compression factor of 30 mm (1.2”) was subtracted. Head center of mass was calculated to be 1.45 m (57”). Given a minimal back angle correction factor, based on rider position on a cruiser motorcycle, the corrected HCOM was 1.4 m (55”).

Based on the distance that the rider was thrown and given an ejection velocity of 16 mph an ejection angle of 42 degrees was computed in this motorcycle accident reconstruction. Hence, it was determined that the rider gained an additional height of 1.2 m (39”) due to ejection, which is added to the rider head center of mass height of 1.4 m (51”), for a total fall height of 2.6 m (8’6”). Using equation 7, an impact velocity of 8.0 m/s (18 mph) was calculated for the rotating fall. Since impact velocity and angle is assumed identical to ejected velocity and angle, travel velocity expressed in terms of its vertical and horizontal components, are 4.8 m/s (10.7 mph) and 5.3 m/s (11.9 mph), respectively. Therefore, the total impact velocity vertical and horizontal components are (8.0 + 4.8) = 12.8 m/s (28.7 mph) and 5.3 m/s (11.9 mph), respectively, with an effective impact angle of 22 degrees relative to the vertical axis.

The helmeted motorcyclist impacted an asphalt roadway, head first. Given the inherently very short stopping distance of such materials, the duration over which the impact velocity was experienced was very short, resulting in high impact accelerations, which produced life-threatening traumatic brain injuries.

The results computed by our motorcycle accident reconstruction model were validated by and corroborated based upon physical evidence from the accident scene as well as the physical evidence of the injuries sustained by the rider.

  1. Conclusions

The motorcycle accident reconstruction model presented herein has been successfully applied to a typical case study involving a single motorcycle collision. Measures of rider anthropometry were incorporated into the model. In the presented motorcycle accident reconstruction case study, the rider’s stature was smaller than that of an average male and seat height was lower than most stock motorcycles. Had average male stature and average motorcycle seat height been utilized, such assumptions would have over-estimated total fall height, thereby producing a calculated vertical impact velocity greater than was actually realized. In certain circumstances, specifically where ejection angle approaches 45 degrees, a simplified model without correction for rider anthropometry and rider posture might produce results that are in disagreement with physical evidence from the accident scene. However, this improved model is not without limitations. Specifically, if a rider were leaning the motorcycle considerably at the time of loss of control, such as when cornering, the initial vertical component (yo) would be reduced. This lean angle could be estimated given the radius of the corner and if the initial speed of the motorcycle can be computed. Overall, the validation of our new motorcycle accident reconstruction model is demonstrated in its application to the motorcycle accident reconstruction case study, which is in agreement with physical evidence from the accident scene.

 8. References

[1]     RnR Market Research (2014) Market Research Reports Press Release: Global motorcycles market demand to rise 7.2% annually to 2016. Published July 31.

[2]    National Safety Council (2013) Injury Facts – 2013 Edition. Itasca, IL..

[3]     Statista – The Statistics Portal. U.S. motorcycle registrations in 2012, by state http://www.statista.com/statistics/191002/number-of-registered-motorcycles-in-the-us-by-state/ accessed 12/23/2015.

[4]     NHTSA’s National Center for Statistics and Analysis (2007) Motorcycles Traffic Safety Fact Sheet (DOT-HS-810-990), 1200 New Jersey Avenue SE, Washington, DC 20590: National Highway Traffic Safety Administration.

[5]     Hurt HH, Ouellet JV, Thom DR (1981) Motorcycle Accident Cause Factors and Identification of Countermeasures. Volume 1: Technical Report. University of Southern California Traffic Safety Center, Los Angeles, CA..

[6]     ACEM (2000) MAIDS (Motorcycle Accidents In Depth Study): In-depth investigations of accidents involving powered two wheelers – Final Report. European Association of Motorcycle Manufacturers, Brussels..

[7]     U.S. Government Accountability Office (2012) Motorcycle Safety: Increasing Federal Funding Flexibility and Identifying Research Priorities Would Help Support States’ Safety Efforts. Report number GAO-13-42.

[8]     Obenski KS (1994) Motorcycle Accident Reconstruction: Understanding Motorcycles. Lawyers & Judges Publishing Co., Tucson, AZ..

[9]     Medwell C, McCarthy J, Shanahan M (1997) Motorcycle Slide to Stop Tests. SAE Technical Paper 970963., SP-1237 Accident Reconstruction and Animation VII, Warrendale, PA

[10]     Southwestern Association of Technical Accident Investigators (1984) Motorcycle Drag Factor Tests. Phoenix, AZ.

[11]     Day TD, Smith JR (1984) Friction Factor for Motorcycles Sliding on Various Surfaces. SAE paper 840250. Society of Automotive Engineers, Warrendale, PA.

[12]     Iowa State Patrol (1985) Motorcycle Test Skidding on its Side, Traffic Investigation Spring Seminar. Johnston, IA..

[13]     Royal Canadian Mounted Police (1984) Motorcycle Testing. Coquitlam, BC, Canada.

[14]     Hague DJ (2001) Calculation of Impact Speed from Pedestrian Slide Distance. Proceedings of The Institute of Traffic Accident Investigators International Conference

[15]    Searle JA, Searle A (1983) The Trajectories of Pedestrians, Motorcycles, Motorcyclists, etc., Following a Road Accident. SAE paper 831622.. Society of Automotive Engineers, Warrendale, PA.

[16]     Thede P, Parks L (2010) Race Tech’s Motorcycle Suspension Bible. Motorbooks International publisher, UK. Cd s.

[17]     Pheasant, S. (1998) Bodyspace. Taylor and Francis, London.

[18]     Gordon CC, Churchill T, Caluser CE, Brandtmiller CB, McConville JT et al. (1989).1988 Anthropometric Survey of US Army Personnel. US Army Technical Report TR-89/044. Natick, MA.

[19]           Barnett, RL (1995) The drunk, the child and the soldier – my how they fall. Triodyne Inc. Safety Bulletin. ISSN 1081-4140. Vol 2 (2).

Research Article “Biomechanics of Motorcycle Accidents” published in Journal of Forensic Biomechanics

Dr. John Lloyd is pleased to announce that his latest research on Motorcycle Accident Biomechanics was published in the Journal of Forensic Biomechanics on January 25th, 2016.

motorcycle accident biomechanics - Dr John Lloyd

Abstract:

Motorcycles are a luxury in the developed world, where they are used mostly for recreation. Whereas in developing countries, motorcycles are required for utilitarian purposes due to lower prices and greater fuel economy. It is estimated that in 2016 there will be more than 134 million motorcycles worldwide, 60-80% of which are in the Asia Pacific and Southern and Eastern Asia regions. In 2011 there were more than 8.2 million registered motorcycles in the United States, representing 3% of all US registered vehicles, with California, Florida and Texas leading the number of motorcycles per state.

In the United States motorcyclists travelled 18.5 billion miles in 2011, which represents only 0.6% of total vehicle miles travelled, yet motorcyclists accounted for 14% (4,612) of traffic fatalities and 4% (81,000) of all occupant injuries 2. According to the U.S. National Highway Traffic Safety Administration (NHTSA), when compared with automobiles, per vehicle mile traveled, motorcyclists’ risk of a fatal crash is 35 times greater than that of a car occupant

In a motorcycle accident, the motorcycle and rider typically become independent, each following their own path to final rest. Consequently, the biomechanical analysis of a motorcycle accident is complex. A biomechanical model to assess rider kinematics associated with motorcycle accidents is presented, which may be important to forensic scientists involved in the analysis of such events. This model can also be applied to other activities, including cycling, equestrian sports, skiing, skating, running, etc.

It is first important to understand the mechanisms by which a rider may be ejected from their motorcycle and how drag factors affect the motorcycle and rider independently. Next we determine rider trajectory, taking into consideration rider anthropometry and posture, results from which are used to derive impact velocity as a function of linear and angular components. A case study is presented, demonstrating how the presented model can be applied to a collision involving a single motorcycle.