Abstract: A system and method for measuring the productivity of a machine is disclosed. The method includes the steps of: obtaining a digital map of a worksite, indicating a geo-fence on the digital map, where the geo-fence defines a portion of the digital map. The method further includes the steps of associating a task to be completed by the machine within the geo-fence, associating a productivity measure with the task; and measuring a machine parameter associated with performance of the task. The method also includes the step of calculating the productivity measure based on the measurement of the machine parameter.

Abstract: A method for ascertaining consumption and/or emission values of at least one vehicle in a traffic area, includes the following steps: determining a number of traffic-technology variables for the traffic area, ascertaining a driving profile of the vehicle based on the traffic-technology variables, assigning an individual consumption and/or emission model and/or a consumption and/or emission model related to the vehicle type group to the driving profile of the vehicle, calculating consumption and/or emission values based on the driving profile and the consumption and/or emission model. In addition, the invention relates to a corresponding method for ascertaining consumption and/or emission values of the vehicle target group of vehicles present in a traffic area and to a method for traffic control employing the consumption and/or emission values. Furthermore, the invention relates to ascertainment systems for ascertaining consumption and/or emission values and to a traffic control system.

Abstract: A method and apparatus for measuring a start fuel flow to a pilot nozzle of a fuel system of a gas turbine engine using pressure differential between fuel passages leading to fuel nozzles.

Abstract: A method of managing operation of a motor vehicle as a function of driving conditions of the vehicle during a journey towards a programmed destination includes: determining driving parameters relative to the journey to be taken; determining a position of the vehicle in the journey; and calculating a drive energy management law (EML) as a function of the position of the vehicle in the journey and of the driving parameters. The calculating the energy management law additionally dynamically calculates a vehicle propulsion mode from various propulsion modes available during the journey, the dynamic calculation including a calculation of a route along the journey as a function of the driving parameters.

Abstract: A fuel economy driving assistance apparatus includes advice provision means for providing a driver with driving advice that contributes to improvement of fuel economy of a vehicle; driving tendency estimation means for estimating a driving tendency of the driver in each driving situation; and advice mode changing means for changing a mode of the driving advice, according to the driving tendency of the driver estimated by the driving tendency estimation means.

Abstract: A method of using locational information for vehicles to determine the cost of traveling on transportation segments is disclosed. The transportation segment costs calculated may be used for many purposes such as providing the lowest cost travel path between two locations at a given time or in general. The cost also may be used to assign tolls and congestion pricing. In addition, the data may be used to determine when a certain vehicle has become less efficient and may require maintenance.

Abstract: A flight management system for an aircraft, for executing a flight plan comprising referenced waypoints comprising a start point, an end point and intermediate waypoints, the said aircraft having a specified fuel quantity at the start of the said flight plan, executes a function of monitoring the fuel consumption with respect to at least one threshold value. The function comprises an operation for estimating if the quantity of fuel remaining on board drops below a threshold at any point in the flight plan included between the start point and the end point, and inserts a corresponding pseudo-waypoint in the flight plan, corresponding to the point where the said threshold is passed. The inserted pseudo-point is displayed on screens for displaying the flight plan.

Abstract: A system and method are described for reducing the cost of efficient vehicles.

Abstract: Systems for simulating vehicle operation include a computer having a pedal activation program, the pedal activation program comprising instructions for generating signals relating to operation of a vehicle from the computer to a pedal sensor output according to a predetermined driving profile. Methods for simulating vehicle operation include providing a computer having a pedal activation program, utilizing the pedal activation program to initiate output signals to a pedal sensor output relating to a vehicle condition and transmitting the output signals to an engine control unit to implement a driving profile programmable within the pedal activation program.

Abstract: This disclosure outlines a method, which enables a vehicle driver to achieve increased fuel efficiency by implementing least-cost route planning based on terrain data and derived from advanced mapping, logging and location based services. Actual fuel efficiency is recorded and correlated by vehicle conditions, time of day and date, and then referenced to achieve the most accurate least-cost route plan for the intended destination.

Abstract: The present invention provides a vehicle display device which can display fuel consumption information of a vehicle in a useful and optimum mode for a driver. A meter_EUC calculates an instantaneous fuel consumption of a vehicle based on a mileage and a fuel injection quantity within a set time, calculates an average fuel consumption of the vehicle based on respective cumulative values of the mileage and the fuel injection quantity repeatedly calculated for every set time, and displays the deviation of the instantaneous fuel consumption with respect to the average fuel consumption as fuel consumption information on a fuel consumption meter. The display on the fuel consumption meter is performed by swinging a pointer with respect to a neutral position.

Abstract: A method of determining fuel consumption in a vehicle through the OBDII bus is described. The fuel consumption is determined by using mass air flow (MAF) sensor data or manifold air pressure (MAP) sensor data, and obtaining and applying long term and short term fuel trim values for the vehicle, which respectively characterize deviations of air-to-fuel stoichiometry in the vehicle due to aging and vehicle's current operating conditions to determine the corrected fuel consumption in the vehicle. For MAP based method, an independent determining of Volumetric Efficiency of a vehicle's engine is also provided. The method is further enhanced by providing various sensing patterns for various sensor data, which depend on the rate of change of the respective data.

Abstract: In an inspection procedure of a completed product of an automatic transmission main body at a unit factory, a control system transmits a control signal to an actuator to receive characteristic data (hardware performance information) output in response to operation of the automatic transmission main body according to the control signal. The hardware performance information of the automatic transmission main body is brought into correspondence with hardware identification information, and set in a database as learning value data. The learning value data of the automatic transmission main body is transferred to a vehicle factory to be aggregated in a database management system at the vehicle factory.

Abstract: A method of driver training to improve fuel economy performance of a vehicle, the method including, receiving selected vehicle and driver operating data indicative of driving conditions and operator inputs captured during previous vehicle operation, processing the received selected vehicle and driver operating data, and generating driving recommendations to improve fuel economy performance based on the processed vehicle and driver operating data.

Abstract: A method for sensing a volume of fluid located in an oil sump of a motor vehicle transmission includes repetitively determining a rate of change of a temperature of the oil, repetitively determining an acceleration of the vehicle, counting the number of occurrences in which vehicle acceleration is greater than a reference acceleration and the rate of change of oil temperature is greater than a reference rate of change of temperature, and producing an indication that the volume of fluid is low, if the number is greater than a reference number.

Abstract: An intelligent fuel oil monitoring system includes a fuel level detector coupled to a fuel tank of a motor vehicle to detect the amount of the fuel oil in the fuel tank, a microcontroller coupled to the fuel level detector to receive traveling data of the motor vehicle and to establish an average speed-fuel consumption relationship curve and fuel consumption and travel distance relationship curves at different speeds and to calculate the distance the motor vehicle can travel based on the amount of the fuel oil detected by the fuel level detector subject to the fuel consumption and travel distance relationship curve, and a display unit coupled to the microcontroller and controlled by the microcontroller to display data.

Abstract: A method is provided for determining when to provide a refueling notification to a driver of a vehicle. A refueling behavior is determined for refueling the vehicle. The refueling behavior is associated at least in part to an amount of fuel customarily remaining in the vehicle when the vehicle is customarily refueled. A remaining amount of fuel in the vehicle and a fuel economy of the vehicle are determined. A distance the vehicle will travel to a next driving destination is estimated. An amount of fuel that will be used to travel to the next driving destination is estimated based on the estimated distance the vehicle will travel to the next driving destination and the fuel economy. A determination is made whether the amount of fuel that will be remaining in the vehicle after the vehicle travels to the next driving destination is less than the amount of a fuel customarily remaining in the vehicle when the vehicle is refueled.

Abstract: Provided is directed to reduce unnecessary fuel consumption due to unnecessary rapid acceleration when a vehicle drives between intersections, and it is an object to allow for economical driving by reducing the fuel cost, and minimize environmental pollution by minimizing the exhaust gas of vehicle, by providing an economical speed for drivers such that vehicles that have passed through an intersection in accordance with the present traffic light economically drives to the next intersection.

Abstract: The present invention includes, among other embodiments, a system embedded in a vehicle including several inputs. The inputs may include one hard coded data, data from sensors on the vehicle, data from external sensors, user coded data, data received from remote databases, data received from broadcast data steams or data that has been accumulated during use of the vehicle. The inputs provide information regarding vehicle speed, motor rpm, motor torque, battery voltage, battery current, and battery charge level, etc. The embedded system also includes a processor unit that receives information from the plurality of inputs and calculates at least an expected vehicle range. The results of any calculations completed by the processing unit is supplied as an output to a display unit, which then displays the information to the user.

Abstract: Fuel supply station information distributing system includes at least one vehicle, an information distributing server and at least one station, which are interconnected through communication line networks. The information distributing server transmits at every given time a request-to-send for vehicle information to the vehicles as well as a request-to-send for station information to the stations. The information distributing server then creates a fuel supply station information associating for each vehicle based on the vehicle information received from the vehicle and the station information received from the stations, and distributes it to the vehicle. When the vehicle receives the fuel supply station information from the information distributing server, it is displayed on the car navigation screen for notifying the driver.

Abstract: A computer-implemented method for managing fuel costs, along with a corresponding apparatus, and a corresponding medium are described. The method includes receiving transaction information at a Network Administrator, the transaction information being associated with: (a) a shipper who has arranged for a shipment of goods from an origin to a destination; and (b) a corresponding carrier that has agreed to transport the shipment using a pre-determined maximum number of eligible units of fuel, where the fuel is purchased by the carrier at a pre-set base price per eligible unit, and where the fuel is purchased from pre-selected fueling locations. The maximum number of eligible units of fuel and the base price per eligible unit for the shipment are established between the shipper and the carrier, while the fueling locations are established by the Network Administrator. The actual price paid for the fuel is set by the market.

Abstract: A method for monitoring fuel status of a vehicle having a fuel tank includes the steps of determining an amount of fuel in the fuel tank, obtaining a geographic location of the vehicle, calculating a fuel threshold based at least in part on the geographic location, and providing a low fuel indication if the amount of fuel is less than the fuel threshold.

Abstract: The present invention relates to a system and a method for displaying an accumulative fuel economic driving area of a vehicle. A system according to an embodiment includes a vehicle information unit that collects vehicle information and a controller that calculates a fuel economic driving area by using the vehicle information, and calculates an accumulative fuel economic driving area by accumulating respective lighting times of respective zones of the fuel economic driving area and calculating respective accumulation ratios of the respective zones. The system provides the driver with information for fuel economic driving.

Abstract: A computer implemented fuel management method and system for monitoring and minimizing a fuel consumption of an aircraft. The fuel management system and method determines, on the basis of model assumptions, a theoretical value relating to the quantity of fuel that is necessary for travelling along at least one sector of a flight route. Furthermore, the fuel management system and method determine a practical value relating to a quantity of fuel that is necessary for travelling along the same sector of the flight route, taking into account actual measured values. Moreover, the system and method compare the theoretical value with the practical value and to provide at least one measure in order to save fuel during a flight when the practical value differs from the theoretical value by a predeterminable amount.

Abstract: A vehicle monitoring device, comprising: a location device for determining location data indicating a location of a vehicle during a journey between an origin point and a destination point; a fuel consumption device for determining fuel consumption data indicating an amount of fuel consumed by the vehicle during the journey, or an emission measurement device for determining emission data indicating an amount of emission produced by the vehicle during the journey; and a vehicle monitoring processor for receiving and processing the location data and the fuel consumption data.

Abstract: A method for monitoring fuel status of a vehicle having a fuel tank includes the steps of determining an amount of fuel in the fuel tank, obtaining a geographic location of the vehicle, calculating a fuel threshold based at least in part on the geographic location, and providing a low fuel indication if the amount of fuel is less than the fuel threshold.

Abstract: Information display systems present information that allows the driver to increase fuel efficiency of a vehicle, such as a hybrid vehicle. In one example, the systems present information in a manner that allows the driver to maximize the time that the hybrid vehicle is able to operate in electric launch mode. One manner is employing a graphical display that generates visual indicators and easily understood graphical representations that display the actual fuel efficiency currently being achieved in comparison to the driver's application of the throttle. As a result, the driver may be able to modify driving habits in order to keep the hybrid vehicle in electric launch mode for as long as possible.

Abstract: The disclosure describes a method and a system for evaluating the driving style of a driver in a motor vehicle with respect to the use of fuel. A disclosed method includes: determining a first value which is characteristic of the current speed of the vehicle; calculation of a second value by low-pass filtering said first value; and evaluating of the driving style with respect to the use of fuel by evaluating the difference between said first value and said second value.

Abstract: A Vehicle Disturbance Estimator determines estimates of a vehicle disturbance force according to vehicle operating conditions. The determined vehicle disturbance force estimate can be used, for example, in connection with controlling a cruise control system for the vehicle, in connection with fuel economy evaluations and testing, and in connection with vehicle diagnostics. A plurality of sets of inputs can be used to determine plural vehicle disturbance estimates for time periods during which a cruise control is on, the vehicle is being driven in the highest gear, and the vehicle is not being braked by any brakes. The plurality of vehicle disturbance estimates can be averaged to provide an output corresponding to an average vehicle disturbance estimate over a plurality of sampling time periods. Kalman filtering can be used to determine the vehicle disturbance estimates.

Abstract: A vehicle fuel informational system is provided with a fuel level determination component, an onboard vehicle positioning component, an onboard vehicle navigation component and a low fuel notification component. The fuel level determination component determines a fuel level of a host vehicle equipped with the vehicle fuel informational system. The onboard vehicle positioning component determines a host vehicle's position of the host vehicle equipped with the vehicle positioning component. The onboard vehicle navigation component provides vehicle route information for a desired vehicle route of the host vehicle. The low fuel notification component provides a low fuel alert notification that is indicative of a low fuel and automatically recommends a suggested fuel provider at least partially based on at least one of the host vehicle's position of the host vehicle and the desired vehicle route.

Abstract: An apparatus is disclosed that includes a haptic actuator operatively associated with a pedal assembly of the vehicle, a human-machine interface (HMI) for enabling the driver to select between a plurality of fuel savings settings, and a controller coupled to a data interface in the vehicle and the HMI interface for causing the haptic actuator to provide feedback to the driver when an aspect of vehicle operation crosses at least one of a plurality of speed and acceleration thresholds responsive to the HMI setting. Additionally, a coaching method provides haptic-based feedback that will not interfere with the operation of the vehicle. This method of closed-loop feedback provides a timely signal to the driver in a way that will encourage a change in driver style over time, such as backing off the accelerator pedal to accelerate at a lower rate and braking earlier with less intensity.

Abstract: A fuel efficiency improvement device for use on each of a plurality of locomotives in a consist includes a processor configured to transmit an initialization message including an identifier and power and fuel consumption rate information for the locomotive on which it is installed to all other locomotives in the consist. One of the devices is chosen to act as a lead device. The lead device is responsible for determining alternative throttle notch settings for each of the locomotives based on the power and fuel consumption rate information in the initialization message. The lead device may be chosen on the basis of identifiers in the initialization messages such as serial numbers. The alternative throttle settings may be determined using greedy value and maximum power calculations.

Abstract: An automated system collects information related to various factors that affect fuel costs, and determines an optimal amount of fuel to be loaded on an aircraft. Information related to an aircraft's fuel efficiency is collected from the aircraft; price information is collected for the stops made by the aircraft; and flight plan information is collected for each flight. The collected information is used to determine or estimate the fuel requirements of the aircraft and an optimal amount of fuel to load onto the aircraft at a location.

Abstract: Disclosed herein is a system for assisting fuel-efficient driving, which can advise a driver to perform fuel-efficient driving by displaying a current fuel economy corresponding to a current driving state on a graph such that a driver can compare the current driving state with a target driving state for achieving an optimum fuel economy of the vehicle.

Abstract: An automated system tracks and records factors that affect fuel consumption. Configuration factors such as the actual engine(s) used in the airplane, weight, weight distribution, engine pressure, engine rotation speeds, etc.; environmental factors such as wind speed and direction, temperature, altitude and air pressure, etc.; and flight path factors such as actual route flown, distance flown, take-off/landing requirements for the airports, etc. are tracked and recorded. The resulting data is used to “normalize” the fuel efficiency of each airplane and engine. Normalized data for an airline's fleet of airplanes and engines are used to find optimal airplane/engine combinations for the routes serviced by the airline. The collected data itself can be sent from the aircraft during flight or, a notification message can be sent from the aircraft to the airline computer system to have the collected data downloaded from the airplane at the next landing.

Abstract: An apparatus is disclosed that includes a haptic actuator operatively associated with a pedal assembly of the vehicle, a human-machine interface (HMI) for enabling the driver to select between a plurality of fuel savings settings, and a controller coupled to a data interface in the vehicle and the HMI interface for causing the haptic actuator to provide feedback to the driver when an aspect of vehicle operation crosses at least one of a plurality of speed and acceleration thresholds responsive to the HMI setting. Additionally, a coaching method provides haptic-based feedback that will not interfere with the operation of the vehicle. This method of closed-loop feedback provides a timely signal to the driver in a way that will encourage a change in driver style over time, such as backing off the accelerator pedal to accelerate at a lower rate and braking earlier with less intensity.

Abstract: A system for improving fuel efficiency of a railroad train located on a railroad train having a locomotive consist including one or more railroad locomotives, said system including a position-determining device, a track profile database including terrain and contour data about a railroad track, and a processor including an algorithm to calculate a load of said train and a feed forward algorithm to determine an acceleration rate and/or a deceleration rate of said train based on said calculated load and forth coming terrain and contour of a railroad track, wherein said change in condition of the track is determined on-board the locomotive consist and the locomotive consist power setting is adjusted to optimize locomotive consist fuel consumption based on the calculated load of the train as the train is proximate to the change in track condition.

Abstract: A system for improving fuel efficiency of a railroad train located on a railroad train having a locomotive consist including one or more railroad locomotives, said system including a position-determining device, a track profile database including terrain and contour data about a railroad track, and a processor including an algorithm to calculate a load of said train and a feed forward algorithm to determine an acceleration rate and/or a deceleration rate of said train based on said calculated load and forth coming terrain and contour of a railroad track, wherein said change in condition of the track is determined on-board the locomotive consist and the locomotive consist power setting is adjusted to optimize locomotive consist fuel consumption based on the calculated load of the train as the train is proximate to the change in track condition.

Abstract: A method for generating a fueling strategy that generally minimizes fueling costs for a specified route to be travelled by a vehicle during a multi-day time period may include, based on current and forecasted fuel prices for the multi-day time period, (i) selecting at least one day during the multi-day time period on which to purchase fuel, (ii) selecting at least one fueling station along the route at which to purchase fuel for each selected day, and (iii) determining an amount of fuel to purchase at each selected fueling station.

Abstract: A method for controlling a powered system, the method including operating the powered system to perform a mission based on an optimized mission plan, identifying when the powered system is approaching a location in the mission where the powered system may change from a first route to a second route, obtaining information about whether the first route or the second route will be taken, and if the second route is taken, adjusting the mission plan to optimize reduced emissions output and/or reduced fuel consumption based on the route change.

Abstract: A method for operating a powered system, the method including determining whether a mission plan of the powered system is correct to satisfy at least one mission objective of the powered system, if not, updating information used to establish the mission plan, revising the mission plan based on the updated information to satisfy the at least one mission objective, and operating the powered system based on the revised mission plan. A system and a computer software code for operating a powered system are also disclosed.

Abstract: A system, method, and computer program product calculate the cost for a traveler to drive the traveler's personal vehicle on a trip of a defined distance and duration, and compare the cost of driving the traveler's personal vehicle to the cost of other transportation options, such as the cost of renting a vehicle and driving the rental vehicle on the trip. In this regard, a system for comparing a cost of driving a traveler's vehicle to a cost of other transportation options comprises a server capable of calculating a total cost to drive the traveler's vehicle on a trip. The server is further capable of calculating a total cost to drive a rental vehicle on the trip. The server is further capable of comparing the total cost to drive the traveler's vehicle on the trip to the total cost to drive the rental vehicle on the trip.

Abstract: Navigation systems and services are described. The navigation services can include obtaining a route or route segment based on a location of a vehicle and a destination. Based on the route, a current fuel supply of the vehicle, and a number of factors related to fuel consumption, a refueling location can be estimated. A number of locations of fuel stations in proximity to the refueling location can be determined and presented to a user, for example, on a map showing the route.

Abstract: A system for providing fuel-efficient driving information for a vehicle includes a fuel-efficient driving area calculation unit and a display unit. The fuel-efficient driving area calculation unit calculates a variable fuel-efficient driving area, which is divided into economical, semi-economical, and uneconomical regions, depending on the increase or decrease of the speed of the vehicle, calculates a current fuel efficiency of the vehicle, receives information about the type and condition of a road from a GPS, and adjusts the regions in the fuel-efficient driving area to prompt the driver to increase or decrease the vehicle speed in advance. The display unit displays the fuel-efficient driving area using information calculated by the fuel-efficient driving area calculation unit, and indicates the current fuel efficiency using the regions.

Abstract: A vehicle hybrid power system is provided according to the present invention. The hybrid power system is characterized by applying the concept of minimum equivalent fuel consumption, and then simulating equivalent fuel consumptions based on respective energy consumption or increase of motor and generator of a motor vehicle, and also defining simulated equivalent fuel consumption formula and making a list of system state parameters, system control parameters, and system negative load parameters, thereby obtaining simulated equivalent fuel consumption multidimensional data by entering the system parameters derived from a discretization/transformation process in the defined simulated equivalent fuel consumption formula; wherein, the simulated equivalent fuel consumption multidimensional data are revised to comprise subsystems, such as system engine, motor, generator, and others to determine a system control strategy of holistic optimization, thereby achieving the objective of saving energy.

Abstract: A method is provided for controlling a hybrid vehicle powertrain, including recording a starting and ending point of a desired route, determining an optimally fuel efficient route, and executing a powertrain control strategy based on the route. Real-time traffic data and topographical data are continuously evaluated, and the route and powertrain control strategy are updated based on the data. A hybrid vehicle is also provided having an engine, a motor/generator, a battery, and a navigation system for receiving a route starting point and ending point. A powertrain control module (PCM) detects the battery charge and determines a powertrain strategy along an optimally fuel efficient route based on the detected charge level when the points are selected, and sustains the charge level in the absence of user-selected route points. Sensors receive real-time traffic data, and the navigation system includes topographical data for determining the optimally fuel efficient route.

Abstract: A flight plan comparison method is provided to be carried out by a display system deployed on an aircraft. The flight plan comparison method includes the steps of storing a group of flight plans and generating a first flight plan comparison page wherein the values of a first type of variable are graphically expressed for a plurality of flight plans in the group of stored flight plans.

Abstract: Parameters having a correlation with a crowded condition of a road traveled by a vehicle are inputted to an ideal fuel consumption estimation model. This ideal fuel consumption estimation model estimates an ideal fuel consumption of vehicle based on the parameters. The ideal fuel consumption of vehicle estimated by the ideal fuel consumption estimation model is outputted to an output portion.

Abstract: An engine is selectively operative in one of a plurality of engine states to transfer torque to an input member of a hybrid transmission. The hybrid transmission is operative to transfer torque between the input member and a torque machine and an output member to generate an output torque in response to an operator torque request. A method for controlling the engine includes monitoring the operator torque request, determining operating power costs associated with a plurality of candidate engine states in response to the operator torque request, determining transition costs for transitioning the engine from a present engine state to each of the candidate engine states, determining stabilization costs for operating the engine in the present engine state and subsequently operating the engine in each of the candidate engine states, and selecting a preferred engine state based upon the operating power costs, the transition costs, and the stabilization costs for the plurality of engine states.

Abstract: A method for operating an engine includes defining a two-dimensional search region based upon an input power transmittable between the internal combustion engine and an electromechanical transmission. The method further includes iteratively dividing the two-dimensional search region into a plurality of subregions based upon one of the input power and the input speed, iteratively determining an engine operating point within each of the subregions, iteratively calculating an operating cost to operate the internal combustion engine and the electromechanical transmission to meet the operator torque request for each engine operating point within each of the subregions, and iteratively identifying the subregion having a minimum operating cost to meet the operator torque request. A preferred engine operating point is determined based upon the engine operating point within the identified subregion having the minimum operating cost to meet the operator torque request.