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: Data is collected during the operation of a vehicle and used to produce a ranking of a driver's 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 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 performance data is displayed in an anonymous format, so that individual drivers cannot be identified unless the driver shares their user ID.

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, a visual alert is presented to the driver. 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. The tiered threshold approach provides a warning to a driver, such that if they correct the behavior triggering the warning, their supervisor is never notified of that behavior. However, if the behavior escalates, and the second threshold is breached, the behavior is recorded.

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 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: Three dimensional GPS or vehicle position data is used to determine a slope the vehicle is traveling over at a specific point in time. The slope data can then be combined with other metrics to provide an accurate, slope corrected vehicle mass. The vehicle mass can then be used along with other vehicle data to determine an amount of work performed by a vehicle, enabling s detailed efficiency analysis of the vehicle to be performed. To calculate slope, horizontal ground speed (VHGS) can be calculated using the Pythagorean Theorem. One can take the Z/Up magnitude and divide it by the horizontal ground speed. Replacing Z, x and y with directional vectors enables one to calculate slope. The slope data is then used to determine the mass of the vehicle at that time. Pervious techniques to calculate mass did not factor in slope, and thus are not accurate.

Abstract: A diagnostic unit is coupled to at least one vehicle control subsystem. The vehicle control subsystem includes one or more of a brake control unit, an engine control unit, and a transmission control unit to provide vehicle data. The diagnostic unit generates diagnostic log information based on the vehicle data and communicates the diagnostic log information to a remote computing device, which hosts a reverse auction to identify at least one vendor that can provide vehicle service based on the diagnostic log information. After identifying the vendor, the diagnostic unit generates and presents service information representing the identified vendor to a vehicle operator via an input/output interface in the vehicle. The input/output interface can accept vehicle data, configuration data, and diagnostic data from the vehicle and the vehicle operator.

Abstract: Three dimensional GPS or vehicle position data is used to determine a slope the vehicle is traveling over at a specific point in time. The slope data can then be combined with other metrics to provide an accurate, slope corrected vehicle mass. The vehicle mass can then be used along with other vehicle data to determine an amount of work performed by a vehicle, enabling s detailed efficiency analysis of the vehicle to be performed. To calculate slope, horizontal ground speed (VHGS) can be calculated using the Pythagorean Theorem. One can take the Z/Up magnitude and divide it by the horizontal ground speed. Replacing Z, x and y with directional vectors enables one to calculate slope. The slope data is then used to determine the mass of the vehicle at that time. Pervious techniques to calculate mass did not factor in slope, and thus are not accurate.

Abstract: System and method for analyzing position data and fuel injector data from a vehicle equipped with a geographical position system (GPS) and fuel injector sensors to enable fuel use patterns of the vehicle to be analyzed. Data defining a flow of fuel through the vehicle's fuel injectors is combined with temporal data and GPS data to produce fuel use encoded GPS data that is transmitted to a remote computer. The fuel use encoded GPS data can be analyzed to determine how much fuel was used by the vehicle during off road use to enable proper fuel tax computations to be performed. The data can also be used to evaluate the mechanical condition of a vehicle. By monitoring fuel use for a trip repeated numerous times, a decrease in fuel efficiency may indicate a mechanical problem (dirty injectors, fouled spark plugs, etc).

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: Three dimensional accelerometer data is used to determine a slope the vehicle is traveling over at a specific point in time. The slope data can then be combined with other metrics to provide an accurate, slope corrected vehicle mass. The vehicle mass can then be used along with other vehicle data to determine an amount of work performed by a vehicle, enabling a detailed efficiency analysis of the vehicle to be performed. To calculate slope, horizontal ground speed (VHGS) can be calculated using the Pythagorean Theorem. One can take the Z/Up magnitude and divide it by the horizontal ground speed. Replacing z, x and y with directional vectors enables one to calculate slope. The slope data is then used to determine the mass of the vehicle at that time. Previous techniques to calculate mass did not factor in slope, and thus are not accurate.

Abstract: A system and method for verifying that an operator was sufficiently close to one or more items to be inspected during an inspection to actually inspect the components, and storing an indication to that effect in a memory accessible via a computer network. In addition to the indication, the memory can store other inspection related data, such as a starting time or ending time of the inspection, or maintenance information about the item that was input during the inspection. The system and method enable a third party application, such as an accounting program or a maintenance program, to access any of the inspection related data.

Abstract: Data is collected during the operation of multiple vehicles in a fleet. Such data can be used by fleet operators for efficiency analysis and improvements; however, the sheer quantity of available data makes such analysis potentially difficult and time consuming. Disclosed herein are several fleet performance monitoring graphical user interfaces (GUI) that simultaneously display different types of fleet data to a user, using combinations of different data types designed to enable fleet users to efficiently manage their fleet by trends and exceptions, which are efficiently and graphically presented to the fleet operator. One such GUI simultaneously displays fleet vehicles on a map, alerts by vehicle, fleet uptime, and maintenance information. In at least one embodiment, the map identifies vehicles having critical alerts using a different color coding than vehicles not associated with such alerts. In at least one embodiment, the fleet uptime metrics simultaneously display vehicle metrics and driver metrics.

Abstract: A handheld, portable device is used to facilitate inspection of vehicles, by generating an electronic vehicle inspection record that can be used by fleet operators to provide evidence of complying with required vehicle inspections. When the vehicle inspection record is generated, route identification data is added to the inspection record. The route identification data defines which of a plurality of predefined routes the vehicle has serviced, or will service, during a time period proximate the inspection of the vehicle. Fleet operators can thus use archived inspection records as evidence of compliance with inspection requirements, and to document what route a vehicle serviced at a particular time.

Abstract: A handheld, portable device is used to facilitate inspection of vehicles, by generating an electronic vehicle inspection record that can be used by fleet operators to provide evidence of complying with required vehicle inspections. When the vehicle inspection record is generated, route identification data is added to the inspection record. The route identification data defines which of a plurality of predefined routes the vehicle has serviced, or will service, during a time period proximate the inspection of the vehicle. Fleet operators can thus use archived inspection records as evidence of compliance with inspection requirements, and to document what route a vehicle serviced at a particular time.

Abstract: System and method for analyzing position data from a vehicle equipped with a geographical position system to determine if the vehicle has adhered to a predetermined schedule, where the vehicle is scheduled to arrive at each one of a plurality of predetermined locations during a corresponding predetermined time window, the position data identifying a specific geographical location of the vehicle at a specific point in time. Position data from the vehicle is collected as the vehicle travels to the plurality of different locations, the position data identifying a specific geographical location of the vehicle at a specific point in time. Then the position data is analyzed to determine whether the vehicle was at each predetermined location during the corresponding predetermined time window. An exception report is automatically generated for each instance that the vehicle was not at one of the plurality of predetermined locations during the corresponding time window.

Abstract: Documents related to delivery of loads shipped by trucking operators can be scanned or otherwise captured using mobile computing devices having document capture and/or document delivery functionality. Load related data can be manually input by drivers during the capture process. Such data can be incorporated into the scanned document as metadata. The concepts disclosed herein encompass establishing a logical connection between the mobile computing device implementing the document capture functionality and a vehicle ECU or vehicle data bus. The document capture application is configured to extract data form the vehicle ECU or vehicle data base and incorporate that data into the document captured. Data, such as location data, can be similarly captured by establish a logical connection with a telematics device including a GPS component. Where the telematics device includes a wireless data link, the capture document can be wirelessly conveyed to a remote data center.

Abstract: Three dimensional accelerometer data is used to determine a slope the vehicle is traveling over at a specific point in time. The slope data can then be combined with other metrics to provide an accurate, slope corrected vehicle mass. The vehicle mass can then be used along with other vehicle data to determine an amount of work performed by a vehicle, enabling s detailed efficiency analysis of the vehicle to be performed. To calculate slope, horizontal ground speed (VHGS) can be calculated using the Pythagorean Theorem. One can take the Z/Up magnitude and divide it by the horizontal ground speed. Replacing Z, x and y with directional vectors enables one to calculate slope. The slope data is then used to determine the mass of the vehicle at that time. Pervious techniques to calculate mass did not factor in slope, and thus are not accurate.

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 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.