Abstract: System and method for collecting object identification data from a plurality of objects that interact with a vehicle during operation of the vehicle, where the vehicle interacts with specific objects at specific geographical positions. An identification sensor is coupled to a geographical position sensor, and whenever an object is identified a record is generated, the record including the identification of the object, the position of the vehicle when the interaction between the object and the vehicle occurs, and the time of the interaction. Exemplary objects include passengers, containers, and documents. Exemplary interactions include loading/unloading an object from the vehicle, boarding a passenger, unloading a passenger, transferring a bulk material from the vehicle into a specific container, and/or transferring a bulk material from a specific container to the vehicle. The record may also include additional data about a parameter of the object (such as the object's weight, volume, or temperature).

Abstract: Data is collected during the operation of a vehicle and used to produce a ranking of a driver's efficiency performance, and that ranking is shared on a hosted website, such that the drivers can compare their performance metrics to their peers. Fleet operators can use these performance metrics as incentives, by linking driver pay with efficiency performance. Individual fleet operators can host their own website, where driver rankings in that fleet can be compared, or the website can be hosted by a third party, and multiple fleet operators participate. The third party can offset their costs for operating the website by charging participating fleet operators a fee, and/or by advertising revenue. In some embodiments, all driver efficiency performance data is displayed in an anonymous format, so that individual drivers cannot be identified unless the driver shares their user ID.

Abstract: System and method for collecting object identification data from a plurality of objects that interact with a vehicle during operation of the vehicle, where the vehicle interacts with specific objects at specific geographical positions. An identification sensor is attached to a particular object that is to be delivered to specific location. A record for the object is generated, the record including the identification of the object, the position of the vehicle when the interaction between the object and the vehicle occurs, and the time of the interaction. The record also include a specific target location for delivery of the object. Exemplary interactions include loading/unloading an object from the vehicle. The record may also include additional data about a parameter of the object (such as the object's weight, volume, or temperature). An alert is sent to a driver of the vehicle when he approaches a location that is adjacent to the delivery location of the vehicle.

Abstract: Disclosed herein are techniques for implementing vehicle ECU reprograming, so the ECU programming, which plays a large role in vehicle performance characteristics, is tailored to current operational requirements, which may be different than the operational characteristics selected by the manufacturer when initially programming the vehicle ECU (or ECUs) with specific instruction sets, such as fuel maps. In one embodiment, a controller monitors the current operational characteristics of the vehicle, determines the current ECU programming, and determines if a different programming set would better suited to the current operating conditions. In the event that the current programming set should be replaced, the controller implements the ECU reprogramming. In a related embodiment, users are enabled to specify the ECU programming to change, such as changing speed limiter settings.

Abstract: A driver efficiency score is based on defining at least metric, collecting data related to the metric during the driver's operation of a vehicle, determining how often the driver's deviated from an optimal standard for that metric, and then reducing the efficiency score based on how often the driver's deviated from the optimal standard, to express the result as an efficiency score of 100% or less (100% meaning the driver never varied from the optimum). The efficiency score for a specific trip is reported along with a loss in dollars due to an efficiency score of less than 100%. Useful metrics include how often the driver deviated from an optimal RPM range (a sweet zone) for the vehicle being operated, how often the driver operated a vehicle at highway speeds without using cruise control, and how often the driver operated a vehicle in excess of a predetermined maximum speed.

Abstract: System and method for collecting object identification data from a plurality of objects that interact with a vehicle during operation of the vehicle, where the vehicle interacts with specific objects at specific geographical positions. An identification sensor is coupled to a geographical position sensor, and whenever an object is identified a record is generated, the record including the identification of the object, the position of the vehicle when the interaction between the object and the vehicle occurs, and the time of the interaction. Exemplary objects include passengers, containers, and documents. Exemplary interactions include loading/unloading an object from the vehicle, boarding a passenger, unloading a passenger, transferring a bulk material from the vehicle into a specific container, and/or transferring a bulk material from a specific container to the vehicle. The record may also include additional data about a parameter of the object (such as the object's weight, volume, or temperature).

Abstract: A method of providing visual feedback to a driver based on data collected during vehicle operation. A processor at the vehicle analyzes vehicle data, and determines when predetermined threshold values have been reached for particular parameters. Whenever such a threshold is reached, an audible indication is provided to the driver, indicating that the baseline has been exceeded. Certain parameters have at least two threshold values. When a first threshold value is reached, an alert is presented to the driver, but no data is recorded or reported. When a second threshold value is reached, another alert is presented to the driver, and data is recorded for reporting to a driver manager or supervisor. This approach provides a driver warning, that if they correct the triggering behavior, their supervisor is never notified of that behavior. However, if the behavior escalates, and the second threshold is breached, the behavior is recorded.

Abstract: A fuel authorization system enables data to be exchanged between vehicles and a gated facility, to verify that the vehicle is authorized to enter the facility. The gated facility is equipped with a camera and a short-range radio (RF) component. Participating vehicles are equipped with fuel authorization component including a RF component that can establish a data link with the gated facility's RF unit. When the camera senses a vehicle in the fuel lane, an RF query is sent to the vehicle. Participating vehicles respond with an action perceivable by the camera. An RF data link is then established between the enrolled vehicle and the gated facility to verify that the vehicle is authorized to receive fuel. Once the verification is complete, the fuel dispenser is enabled.

Abstract: A fuel authorization system enables data to be exchanged between vehicles and a fuel vendor, to verify that the vehicle is authorized to receive fuel. Each fuel island is equipped with a camera and a short range radio (RF) component. Participating vehicles are equipped with fuel authorization component including an IR transmitter and a RF component that can establish a data link with the fuel island's RF unit. When the camera senses a vehicle in the fuel lane, an RF query is sent to the vehicle. Participating vehicles respond with an IR transmission. An RF data link is then established between the enrolled vehicle and the fuel vendor to verify that the vehicle is authorized to receive fuel. Once the verification is complete, the fuel dispenser is enabled. In some embodiments, the IR data link is not required, as the camera can distinguish between multiple fuel lanes.

Abstract: System and method for collecting object identification data from a plurality of objects that interact with a vehicle during operation of the vehicle, where the vehicle interacts with specific objects at specific geographical positions. An identification sensor is coupled to a geographical position sensor, and whenever an object is identified a record is generated, the record including the identification of the object, the position of the vehicle when the interaction between the object and the vehicle occurs, and the time of the interaction. Exemplary objects include passengers, containers, and documents. Exemplary interactions include loading/unloading an object from the vehicle, boarding a passenger, unloading a passenger, transferring a bulk material from the vehicle into a specific container, and/or transferring a bulk material from a specific container to the vehicle. The record may also include additional data about a parameter of the object (such as the object's weight, volume, or temperature).

Abstract: Described herein is a fuel authorization program that vehicles enrolled in the fuel authorization program to provide fuel tank sensor data in each fuel authorization request, so that an amount of fuel authorized will be limited to the amount needed to fill the vehicle's fuel tank, reducing a likelihood that fuel will be diverted. In at least some embodiments, the fuel authorization controller at the vehicle automatically uses the fuel tank sensor data and known tank size to include in a fuel authorization request sent to a fuel vendor data defining how much fuel is required to fill the vehicle fuel tanks. In at least some embodiments, the fuel vendor consults data from a source other than the vehicle (such as records maintained by the fuel authorization program) to determine how large the vehicles fuel tanks are, and to calculate how much fuel is required.

Abstract: System and method for collecting object identification data from a plurality of objects that interact with a vehicle during operation of the vehicle, where the vehicle interacts with specific objects at specific geographical positions. An identification sensor is coupled to a geographical position sensor, and whenever an object is identified a record is generated, the record including the identification of the object, the position of the vehicle when the interaction between the object and the vehicle occurs, and the time of the interaction. Exemplary objects include passengers, containers, and documents. Exemplary interactions include loading/unloading an object from the vehicle, boarding a passenger, unloading a passenger, transferring a bulk material from the vehicle into a specific container, and/or transferring a bulk material from a specific container to the vehicle. The record may also include additional data about a parameter of the object (such as the object's weight, volume, or temperature).

Abstract: Described herein is a fuel authorization program that vehicles enrolled in the fuel authorization program to provide fuel tank sensor data in each fuel authorization request, so that an amount of fuel authorized will be limited to the amount needed to fill the vehicle's fuel tank, reducing a likelihood that fuel will be diverted. In at least some embodiments, the fuel authorization controller at the vehicle automatically uses the fuel tank sensor data and known tank size to include in a fuel authorization request sent to a fuel vendor data defining how much fuel is required to fill the vehicle fuel tanks. In at least some embodiments, the fuel vendor consults data from a source other than the vehicle (such as records maintained by the fuel authorization program) to determine how large the vehicles fuel tanks are, and to calculate how much fuel is required.

Abstract: Disclosed herein are techniques and structures to update vehicle controller programming in a vehicle. Such updating includes logically coupling at least one data link to a vehicle controller and alerting a driver, via an output device, about an impending update to the vehicle controller. Approval for the wirelessly received impending update to the vehicle controller is received from the driver via an input device. The controller update from a remote source is passed via the at least one data link; and upon receiving the controller update, the controller update is used to change programming of the vehicle controller.

Abstract: Described herein is a fuel authorization program that requires data to be dynamically retrieved from a vehicle data bus during the fuel authorization process. This can be implemented using a smart cable that is installed in enrolled vehicles. The smart cable includes a housing suitable for commercial environments, a cable to logically couple the smart cable to the vehicle data bus, a second data link to be used to logically couple the smart cable to a fuel authorization “puck” in a vehicle, and a controller. The puck handles communication with the fuel vendor. The controller automatically implements the functions responding to a query from the puck received over the second data link by dynamically acquiring data from the vehicle data bus using the first data link, and conveying the data to the puck using the second data link.

Abstract: Disclosed herein are techniques for implementing vehicle ECU reprogramming, so the ECU programming, which plays a large role in vehicle performance characteristics, is tailored to current operational requirements, which may be different than the operational characteristics selected by the manufacturer when initially programming the vehicle ECU (or ECUs) with specific instruction sets, such as fuel maps. In one embodiment, a controller monitors the current operational characteristics of the vehicle, determines the current ECU programming, and determines if a different programming set would better suited to the current operating conditions. In the event that the current programming set should be replaced, the controller implements the ECU reprogramming. In a related embodiment, users are enabled to specify the ECU programming to change, such as changing speed limiter settings.

Abstract: A fuel authorization program based on equipping fuel station, fuel pumps, and vehicles with components to enable automatic fuel authorization for enrolled vehicles. The program includes fuel pumps including a pump transmitting sensor that automatically emits a pump ID. As a vehicle pulls in next to the pump a vehicle coupling receiving sensor detects the pump ID signal and a proximity link is created. The vehicle sensor passes the pump ID via hardwire or Bluetooth to vehicle fuel authorization processor (which can be part of a telematics device). The vehicle processor transmits the pump ID (and any fuel authorization credentials needed, such as a PIN or VIN) via WI-FI to a Station processor for fuel vendor authorization. If approved, the pump is enabled. As the vehicle moves away the coupling sensor link is broken and the vehicle transmits a “disconnect” message via Wi-Fi and the pump is disabled.

Abstract: A fuel authorization system enables data to be exchanged between vehicles and a fuel vendor, to verify that the vehicle is authorized to receive fuel. Each fuel island is equipped with a camera and a short range radio (RF) component. Participating vehicles are equipped with fuel authorization component including an IR transmitter and a RF component that can establish a data link with the fuel island's RF unit. When the camera senses a vehicle in the fuel lane, an RF query is sent to the vehicle. Participating vehicles respond with an IR transmission. An RF data link is then established between the enrolled vehicle and the fuel vendor to verify that the vehicle is authorized to receive fuel. Once the verification is complete, the fuel dispenser is enabled. In some embodiments, the IR data link is not required, as the camera can distinguish between multiple fuel lanes.

Abstract: Disclosed herein are techniques for implementing vehicle ECU reprograming, so the ECU programming, which plays a large role in vehicle performance characteristics, is tailored to current operational requirements, which may be different than the operational characteristics selected by the manufacturer when initially programming the vehicle ECU (or ECUs) with specific instruction sets, such as fuel maps. In one embodiment, a controller monitors the current operational characteristics of the vehicle, determines the current ECU programming, and determines if a different programming set would better suited to the current operating conditions. In the event that the current programming set should be replaced, the controller implements the ECU reprogramming. In a related embodiment, users are enabled to specify the ECU programming to change, such as changing speed limiter settings.

Abstract: Position data received wirelessly from a vehicle enrolled in an inspection waiver program are employed to determine when the enrolled vehicle is approaching an inspection station. After determining that the enrolled vehicle is approaching an inspection station, and if the enrolled vehicle has a valid inspection waiver, a bypass confirmation can selectively be provided to the vehicle operator, authorizing the operator to bypass the inspection station. The task of determining when an enrolled vehicle is approaching the location of an inspection station can be performed using a processor disposed in the vehicle, or at a remote location separate from both the vehicle and the inspection station, or at the inspection station. The inspection stations can be mobile so that their locations are varied to prevent operators from intentionally avoiding an inspection, as may occur with fixed inspection stations.