Abstract: A management server is configured to perform a process including: setting a basic fee of a first monthly fee when a utilization manner is battery lease; setting discount rates based on the weight, capacity, manufacturer, degree of initial deterioration, amount of power consumption, number of times of performing quick electric charging, utilization region, and utilization period of the battery; determining the first monthly fee; setting a basic fee of a second monthly fee when the utilization manner is vehicle lease; setting discount rates based on the weight of the battery, a utilization region of the vehicle, and a utilization period; determining the second monthly fee; and determining a total monthly fee.

Abstract: A management server is configured to perform a process including: setting a basic fee of a first monthly fee when a utilization manner is battery lease; setting discount rates based on the weight, capacity, manufacturer, degree of initial deterioration, amount of power consumption, number of times of performing quick electric charging, utilization region, and utilization period of the battery; determining the first monthly fee; setting a basic fee of a second monthly fee when the utilization manner is vehicle lease; setting discount rates based on the weight of the battery, a utilization region of the vehicle, and a utilization period; determining the second monthly fee; and determining a total monthly fee.

Abstract: A management server performs a process including: when there is a request to partially replace a battery, obtaining a usage history of the battery; obtaining each cell's full charge capacity; determining a cell having a smallest full charge capacity as a cell to be replaced; calculating an average value of the full charge capacities of the plurality of cells excluding the cell to be replaced; extracting a selectable cell from inventory information; selecting a replacement cell; setting a replacement fee corresponding to partial replacement; and when entire replacement is requested, setting a replacement fee corresponding to entire replacement.

Abstract: A management server is configured to perform a process including: a step of obtaining a utilization history of each user in the previous month when a condition for performing a dividing ratio setting process is satisfied; a step of updating a utilization record evaluation; a step of calculating a first dividing ratio; a step of updating a driving record evaluation; a step of calculating a second dividing ratio; and a step of setting a dividing ratio.

Abstract: A management server is configured to perform a process including: obtaining, when an electric vehicle is returned, returning date and time, a returning location, and a use history of a vehicle; setting a fee-returning rate in accordance with a SOC at the time of renting, a SOC at the time of returning, the number of times of performing behaviors contributing to deterioration of a battery, and a leaving time in a state contributing to the deterioration of the battery; setting a correction coefficient in accordance with a cause of a behavior contributing to the deterioration; setting the fee-returning rate in accordance with the returning location and the returning time; determining the fee-returning rate; and performing a process for providing points corresponding to the fee-returning amount.

Abstract: A management server performs a process including: when an electric vehicle is returned, obtaining a usage history of the vehicle; calculating a ratio of a non-traveling period of time of the vehicle; setting a discount rate based on the ratio of the non-traveling period of time; setting a discount rate based on how many times the vehicle is rapidly accelerated; setting a discount rate based on how many times the vehicle is rapidly decelerated; setting a discount rate based on environmental temperature; setting a discount rate based on a parking environment; setting a discount rate based on an SOC history; and setting a rental fee.

Abstract: When a management server receives a request for reservation cancellation, the management server performs a process including: a step of specifying a user and obtaining reservation information; a step of adding “1” to the number of cancellations having a large degree of influence when a period until the next reservation is within A hours; a step of calculating an estimate of the rental fee applied after the reservation cancellation is confirmed, when the number of cancellations having a large degree of influence after the addition is more than or equal to a threshold value; and a step of notifying the estimate.

Abstract: When returning an electric vehicle, a management server performs a process including: a step of specifying a return date and time and a user; a step of obtaining return station information; a step of setting a discount rate corresponding to a first difference between the number of electric vehicles that can be charged and the number of parked low-SOC vehicles; a step of setting a discount rate corresponding to prediction of increase or decrease of the number of electric vehicles at the time of returning; a step of setting a discount rate corresponding to a second difference between the number of electric vehicles that can be parked and the number of parked electric vehicles; and a step of setting a rental fee based on the set discount rates.

Abstract: A management server is configured to perform a process including: a step of obtaining a utilization history of each user in the previous month when a condition for performing a dividing ratio setting process is satisfied; a step of updating a utilization record evaluation; a step of calculating a first dividing ratio; a step of updating a driving record evaluation; a step of calculating a second dividing ratio; and a step of setting a dividing ratio.

Abstract: When a condition for setting a fee is established, a management server performs: determining a target of setting the fee; obtaining a utilization plan; when a nationwide utilization plan is not selected and a set-area utilization plan is instead selected, setting a correction coefficient C(1) corresponding to the number of stations; setting a correction coefficient C(3) corresponding to the number of stations each with an electric charging device; setting a correction coefficient C(4) corresponding to the number of stations each with a quick electric charging device; obtaining a utilization history; and when there is no utilization beyond the plan, setting a monthly fee.

Abstract: A management server is configured to perform a process including: obtaining, when an electric vehicle is returned, returning date and time, a returning location, and a use history of a vehicle; setting a fee-returning rate in accordance with a SOC at the time of renting, a SOC at the time of returning, the number of times of performing behaviors contributing to deterioration of a battery, and a leaving time in a state contributing to the deterioration of the battery; setting a correction coefficient in accordance with a cause of a behavior contributing to the deterioration; setting the fee-returning rate in accordance with the returning location and the returning time; determining the fee-returning rate; and performing a process for providing points corresponding to the fee-returning amount.

Abstract: A management server performs a process including: when an electric vehicle is returned, obtaining a usage history of the vehicle; calculating a ratio of a non-traveling period of time of the vehicle; setting a discount rate based on the ratio of the non-traveling period of time; setting a discount rate based on how many times the vehicle is rapidly accelerated; setting a discount rate based on how many times the vehicle is rapidly decelerated; setting a discount rate based on environmental temperature; setting a discount rate based on a parking environment; setting a discount rate based on an SOC history; and setting a rental fee.

Abstract: A management server performs a process including: when there is a request to partially replace a battery, obtaining a usage history of the battery; obtaining each cell's full charge capacity; determining a cell having a smallest full charge capacity as a cell to be replaced; calculating an average value of the full charge capacities of the plurality of cells excluding the cell to be replaced; extracting a selectable cell from inventory information; selecting a replacement cell; setting a replacement fee corresponding to partial replacement; and when entire replacement is requested, setting a replacement fee corresponding to entire replacement.

Abstract: A management server is configured to perform a process including: setting a basic fee of a first monthly fee when a utilization manner is battery lease; setting discount rates based on the weight, capacity, manufacturer, degree of initial deterioration, amount of power consumption, number of times of performing quick electric charging, utilization region, and utilization period of the battery; determining the first monthly fee; setting a basic fee of a second monthly fee when the utilization manner is vehicle lease; setting discount rates based on the weight of the battery, a utilization region of the vehicle, and a utilization period; determining the second monthly fee; and determining a total monthly fee.

Abstract: A vehicle control apparatus computes a fuel consumption decrease or a fuel consumption increase for each of a plurality of travel modes. The vehicle control apparatus includes a control section that calculates an engine efficiency of an engine and an MG-INV efficiency which is a combined efficiency of a motor generator and an inverter. The engine efficiency is calculated based on an engine power and an ideal fuel consumption line. The MG-INV efficiency is calculated based on an MG power. As such, based on the engine efficiency and the MG-INV efficiency, the control section computes the per-unit-electric-power fuel consumption decrease or the per-unit-electric-power fuel consumption increase.

Abstract: A vehicle control apparatus uses a travel mode selection unit to select between an EV travel mode, an engine travel mode, and an engine generation mode depending on comparisons between an engine generated power cost, an EV effect, and a surplus electric energy. In such manner, according to a travel condition of a vehicle, an appropriate travel mode is selected for an improvement of fuel consumption efficiency. The vehicle control apparatus also computes a fuel consumption decrease or a fuel consumption increase for each of a plurality of travel modes based on an engine efficiency and an MG-INV efficiency. In such manner, fuel consumption increase/decrease for every travel mode may be computed.

Abstract: A vehicle controller performs a throttle-valve-late-close control in which the throttle valve is held open until a delay time has passed after the fuel cut is started, and an EGR-valve-open-close control in which the EGR valve is repeatedly opened and closed. Then, the throttle valve is closed and the EGR valve is opened. In a period from a latter period of an exhaust stroke to a preceding period of an intake stroke, a valve-overlap control is executed so that a variable valve timing controller is controlled to make both an intake valve and an exhaust valve opened. A pumping loss of an engine is sufficiently reduced and an energy-regenerate efficiency can be effectively improved.

Abstract: A vehicle control apparatus uses a travel mode selection unit to select between an EV travel mode, an engine travel mode, and an engine generation mode depending on comparisons between an engine generated power cost, an EV effect, and a surplus electric energy. In such manner, according to a travel condition of a vehicle, an appropriate travel mode is selected for an improvement of fuel consumption efficiency. The vehicle control apparatus also computes a fuel consumption decrease or a fuel consumption increase for each of a plurality of travel modes based on an engine efficiency and an MG-INV efficiency. In such manner, fuel consumption increase/decrease for every travel mode may be computed.

Abstract: A vehicle control apparatus computes a fuel consumption decrease or a fuel consumption increase for each of a plurality of travel modes. The vehicle control apparatus includes a control section that calculates an engine efficiency of an engine and an MG-INV efficiency which is a combined efficiency of a motor generator and an inverter. The engine efficiency is calculated based on an engine power and an ideal fuel consumption line. The MG-INV efficiency is calculated based on an MG power. As such, based on the engine efficiency and the MG-INV efficiency, the control section computes the per-unit-electric-power fuel consumption decrease or the per-unit-electric-power fuel consumption increase.

Abstract: A vehicle controller performs a throttle-valve-late-close control in which the throttle valve is held open until a delay time has passed after the fuel cut is started, and an EGR-valve-open-close control in which the EGR valve is repeatedly opened and closed. Then, the throttle valve is closed and the EGR valve is opened. In a period from a latter period of an exhaust stroke to a preceding period of an intake stroke, a valve-overlap control is executed so that a variable valve timing controller is controlled to make both an intake valve and an exhaust valve opened. A pumping loss of an engine is sufficiently reduced and an energy-regenerate efficiency can be effectively improved.