2022 LUCID AIRVIN: 50EA1GBA4NA001956

Anti-lock Braking System (ABS) means a portion of a service brake system that automatically controls the degree of rotational wheel slip during braking by: (1) Sensing the rate of angular rotation of the wheels; (2) Transmitting signals regarding the rate of wheel angular rotation to one or more controlling devices that interpret those signals and generate responsive controlling output signals; and (3) Transmitting those controlling signals to one or more modulator devices that adjust brake actuating forces in response to those signals.

An auto-reverse system enables power windows and sunroofs on motor vehicles to automatically reverse direction when such power windows and panels detect an obstruction. This feature can prevent children and others from being trapped, injured, or killed by the power windows and sunroofs.

ESC is a computerized technology that improves a vehicle's stability by detecting and reducing loss of traction (skidding). When ESC detects loss of steering control, it automatically applies the brakes to help steer the vehicle in the driver's intended direction. Braking is automatically applied to wheels individually, such as the outer front wheel to counter oversteer, or the inner rear wheel to counter understeer. Some ESC systems also reduce engine power until control is regained.

A keyless ignition system permits starting a car without a physical key being inserted into an ignition. Instead, a small device known as a "key fob" transmits a code to a computer in the vehicle when the fob is within a certain close range. When the coded signal matches the code embedded in the vehicle's computer, a number of systems within the car are activated, including the starter system. This allows the car to be started by simply pressing a button on the dashboard while the key fob is left in a pocket or a purse. The vehicle is usually shut down by pushing the same button.

A TPMS is an electronic system designed to monitor the air pressure inside the pneumatic tires on various types of vehicles. TPMS can be divided into two different types - direct and indirect. Direct TPMS employ pressure sensors on each wheel, either internal or external. The sensors physically measure the tire pressure in each tire and report it to the vehicle's instrument cluster or a corresponding monitor. Indirect TPMS does not use physical pressure sensors but measure air pressures by monitoring individual wheel rotational speeds and other signals available outside of the tire itself.

When the traction control computer detects a driven wheel or wheels spinning significantly faster than another, it invokes an electronic control unit to apply brake friction to wheels spinning due to loss of traction. This braking action on slipping wheels will cause power transfer to the wheels with traction due to the mechanical action within the differential.

An ACN system notifies emergency responders that a crash has occurred and provides its location.

A backup camera, also known as a rearview video system, helps prevent back-over crashes and protects our most vulnerable people - children and senior citizens - by providing an image of the area behind the vehicle. A backup camera helps the driver see behind the vehicle while in reverse.

A parking assist system uses computer processors, back up cameras, surround-view cameras, and sensors to assist with steering and other functions during parking. Drivers may be required to accelerate, brake, or select gear position. Some systems are capable of parallel and perpendicular parking. Drivers must constantly supervise this support feature and maintain responsibility for parking.

A rear cross traffic alert system warns the driver of a potential collision, while in reverse, which may be outside the view of the backup camera.

A CIB system is an automatic emergency braking system designed to detect an impending forward crash with another vehicle. CIB systems automatically apply the brakes in a crash imminent situation to slow or stop the vehicle, avoiding the crash or reducing its severity, if the driver does not brake in response to a forward collision alert.

A DBS system is an automatic emergency braking system designed to detect an impending forward crash with another vehicle. DBS systems automatically supplement the driver's braking in an effort to avoid a crash if the driver does not brake hard enough to avoid it.

An FCW system monitors a vehicle's speed, the speed of the vehicle in front of it, and the distance between the vehicles. If the vehicles get too close due to the speed of either vehicle, the FCW system will warn the driver of the rear vehicle of an impending crash so that the driver can apply the brakes or take evasive action, such as steering, to prevent a potential crash. FCW systems provide an audible, visual, or haptic warning, or any combination thereof, to alert the driver of an FCW-equipped vehicle of a potential collision.

A PAEB system provides automatic braking for vehicles when pedestrians are in front of the vehicle and the driver has not acted to avoid a crash.

BSI helps prevent a collision with a vehicle in the driver's blind spot. If the driver ignores the blind spot warning and starts to change to a lane where there's a vehicle, the system activates and automatically applies light braking pressure, or provides steering input, to guide the vehicle back into the original lane. The system monitors for vehicles in the driver's blind spot using rear-facing cameras or proximity sensors.

BSW alerts drivers with an audio or visual warning if there are vehicles in adjacent lanes that the driver may not see when making a lane change.

A lane centering assistance system utilizes a camera-based vision system designed to monitor the vehicle's lane position and automatically and continuously apply steering inputs needed to keep the vehicle centered within its lane.

An LDW system monitors lane markings and alerts the driver if their vehicle drifts out of their lane without a turn signal or any control input indicating the lane departure is intentional. An audio, visual or other alert warns the driver of the unintentional lane shift so the driver can steer the vehicle back into its lane.

An LKA system prevents a driver from unintentionally drifting out of the intended travel lane. LKA systems use information provided by Lane Departure Warning (LDW) system sensors to determine whether a vehicle is about to unintentionally move out of its lane of travel. If so, LKA activates and corrects the steering, brakes or accelerates one or more wheels, or does both, resulting in the vehicle returning to its intended lane of travel.

ADB is a type of front-lighting system that lets upper beam headlamps adapt their beam patterns to create shaded areas around oncoming and preceding vehicles to improve long-range visibility for the driver without causing discomfort, distraction, or glare to other road users.

DRL is an automotive lighting system on the front of a vehicle or bicycle, that automatically switches on when the vehicle is in drive, and emits white, yellow, or amber light to increase the conspicuity of the vehicle during daylight conditions.

A headlamp light source provides a distribution of light designed to provide adequate forward and lateral illumination with limits on light directed towards the eyes of other road users, to control glare. This beam is intended for use whenever other vehicles are present ahead. Halogen, high-Intensity discharge (HID), light-emitting diode (LED), and laser are the most common headlights on the market.

A semi-automatic headlamp beam switching device provides automatic or manual control of beam switching at the option of the driver. When the control is automatic, the headlamps switch from the upper beam to the lower beam when illuminated by the headlamps on an approaching car and switch back to the upper beam when the road ahead is dark. When the control is manual, the driver may obtain either beam manually regardless of the condition of lights ahead of the vehicle.

ACC automatically adjusts the vehicle's speed to keep a pre-set distance from the vehicle in front of it.

Electrification level defines to what level the vehicle is powered by electric system. The common electric system configurations are mild hybrid, strong hybrid, plug-in hybrid, battery electric, and fuel cell vehicles.

(1) Mild hybrid is the system such as 12-volt start-stop or 48-volt belt integrator starter generator (BISG) system that uses an electric motor to add assisting power to the internal combustion engine. The system has features such as stop-start, power assist, and mild level of generative braking features.

(2) Strong hybrid systems, in vehicles such as the Toyota Prius, mainly consist of motors, conventional gasoline engine, and battery, but the source of electrical charge for the battery power is provided by the conventional engine and/or regenerative braking.

(3) Plug-in hybrid systems, in vehicles such as the Toyota Rav4 Prime, mainly consist of motors, conventional gasoline engine and battery. Plug-in hybrid vehicles are like strong hybrids, but they have a larger battery pack and can be charged with an external source of electricity by electric vehicle supply equipment (EVSE).

(4) Battery electric vehicles (BEV), such as the Tesla Model S or Nissan Leaf, have only a battery and electrical motor components and use electricity as the only power source.

(5) Fuel cell electric vehicles (FCEV) use full electric drive platforms but consume electricity generated by onboard fuel cells and hydrogen fuel.

This field stores engine power in kilowatts (kW).

Fuel type defines the fuel used to power the vehicle. For vehicles that have two power sources, such as plug-in hybrid vehicle, both primary fuel type and secondary fuel type will be provided.

Body Class presents the body type based on 49 CFR 565.12(b): "Body type means the general configuration or shape of a vehicle distinguished by such characteristics as the number of doors or windows, cargo-carrying features and the roofline (e.g., sedan, fastback, hatchback)." Definitions are not provided for individual body types in the regulation.

This is a numerical field to store the number of doors on a vehicle.

Per 49 CFR 565, Make is a name that a manufacturer applies to a group of vehicles or engines.

Per 49 CFR 565, Model means a name that a manufacturer applies to a family of vehicles of the same type, make, line, series and body type.

If the model year (MY) is supplied when the VIN is decoded, such as from a crash report or a vehicle registration record, the MY value will be the supplied MY, even if the MY decoded from the VIN differs from the supplied MY. If the MY is not supplied when the VIN is decoded, the MY value will be decoded from the 10th character in the VIN.

This data element captures the city of the manufacturing plant where the manufacturer affixes the VIN.

This data element captures the country of the manufacturing plant where the manufacturer affixes the VIN.

This data element captures the State or Province name within the Plant Country of the manufacturing plant where the manufacturer affixes the VIN.

Per 49 CFR 565, Series means a name that a manufacturer applies to a subdivision of a "line" denoting price, size or weight identification and that is used by the manufacturer for marketing purposes.

This data element captures additional information about series of the vehicle.

This field defines the type of the vehicle based on the World Manufacturer Identifier (WMI).

This data element is a numeric field to capture the number of rows of seats in a vehicle.

This data element is a numeric field to store the number of seats in a vehicle.

An internal NHTSA field to capture the body type of the vehicle.

An internal NHTSA field to capture the Make of the vehicle.

An internal NHTSA field to capture the Model of the vehicle.

Battery Energy (kWh) From field stores the lower bound of battery energy range in the unit of kilowatt-hour (kWh).

Battery type field stores the battery chemistry type for anode, cathode.

EV Drive Unit field stores electric vehicle (EV) motor configuration for single or dual motor.

There are three levels of battery chargers currently. Level 1 and 2 are AC chargers; Level 3 is a DC charger. Chargers at each level charge batteries with different voltage and current levels. Level 3 is the fastest charging.

-Level 1

• AC charger.
• In North America this typically means 16 amps at 120 volts delivering 1.9 kW of power.
• In Europe it may be 13 or 16 amps at 240 volts delivering 3 kW of power.
• The EV may incorporate a standard domestic power cord to connect the vehicle to a domestic socket outlet or a Level 1 charging station.

-Level 2

• AC charger.
• It delivers up to 20 kW of power from either single- or three-phase alternating current (AC) sources of 208-240 volts at up to 80 amps.

-Level 3

• DC charging, or "fast charging."
• To achieve very short charging times, Level 3 chargers supply very high currents of up to 400 amps at voltages up to 600 volts DC delivering a maximum power of 240 kW.

Transmission speed is a numerical field to capture the number of speeds for a transmission, such as 6 for a six-speed automatic or manual transmission.

Transmission style provides information about the type of transmissions. The major types of transmissions are manual transmission, automatic transmission, continuously variable transmission (CVT), and dual-clutch transmission (DCT).

Other Restraint Info field is used to code additional information about restraint system that cannot be coded in any other restraint fields.

This field describes the type of seat belt, such as manual or automatic. Automatic seat belts automatically close over riders in a vehicle. Automatic seat belts were mainly used in some older model GM, Nissan, and Honda vehicles and are rarely seen now.

This field captures the location of curtain air bags. Curtain air bags are side air bags that protect the head.

This field captures the location of frontal air bags. Frontal air bags are generally designed to deploy in "moderate to severe" frontal or near-frontal crashes.

This field captures the location of knee air bags, which deploy from a car's lower dashboard, are meant to distribute impact forces on an occupant's legs in the case of a crash, thereby reducing leg injuries.

This field captures the location of side air bags, typically designed for three areas of added protection: chest/torso, head, or both.