JP6728968B2 - Display control method and display control device - Google Patents

Description

The present invention relates to a display control method and a display control device for controlling display of a cruising range.

BACKGROUND ART Conventionally, there is known a technique of calculating a cruising distance of a vehicle based on an instantaneous electricity cost and a remaining electricity amount of a battery and displaying the calculated cruising distance (for example, Patent Document 1).

JP 2012-100474A

However, in the related art, when the cruising range is calculated, the calculated cruising range is instantly displayed to the user, so that the user may not be able to grasp that the cruising range has changed.

The problem to be solved by the present invention is to provide a display control method and a display control device that allow a user to appropriately grasp that the cruising range has changed.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to repeatedly calculate the cruising range, and display the current cruising range, which is the cruising range calculated this time, next to the previous cruising range, which is the previously calculated cruising range. In the display control method or display control device, calculate the distance between the previous cruising range and the current cruising range as the transition cruising range, and display the transition cruising range before displaying the current cruising range. Then, the above problem is solved.

According to the present invention, before the current cruising distance is displayed, by displaying the transition cruising distance, which is the distance between the previous cruising distance and the current cruising distance, it is possible to detect that the cruising distance has changed. , It is possible to make the user properly understand.

It is a block diagram which shows the structure of the vehicle-mounted apparatus which concerns on this embodiment. It is a flow chart which shows display control processing concerning this embodiment. It is a figure for explaining a display control method in the scene where the cruising distance of the vehicle changed by user's operation. It is a figure for demonstrating the display control method in the scene where the cruising range of a vehicle changed by user's operation, while displaying a transition cruising range. It is a figure for explaining a display control method in the scene where the amount of change of the cruising range by a user's operation is less than a predetermined value.

Embodiments of the present invention will be described below with reference to the drawings. In the present embodiment, the present invention will be described by exemplifying an on-vehicle device mounted on an engine vehicle.

FIG. 1 is a diagram showing a configuration of an in-vehicle device 100 according to the present embodiment. As shown in FIG. 1, the in-vehicle device 100 according to the present embodiment includes an engine control device 110, an in-vehicle device 120, a vehicle speed sensor 130, a fuel sensor 140, a display control device 150, and a display device 160. doing. These devices are connected by a CAN (Controller Area Network) or other vehicle-mounted LAN in order to exchange information with each other.

The engine control device 110 acquires information on the fuel injection amount from a fuel injection amount sensor (not shown), and controls the operation of the internal combustion engine based on the acquired information on the fuel injection amount. The engine control device 110 also outputs information on the fuel injection amount to the display control device 150.

The in-vehicle device 120 is an operation member that can be operated by the user. Such an on-vehicle device 120 includes one that changes the cruising range of the vehicle by the user operating the on-vehicle device 120. As an example of the vehicle-mounted device 120 that changes the cruising distance of the vehicle, an eco-mode switch that switches between an “eco mode” that assists accelerator control so as to reduce fuel consumption of the vehicle and a “normal mode”, and an air conditioner on/off An example is an air conditioner switch that switches off. For example, when the user operates the eco-mode switch to set to "eco-mode", the cruising range of the vehicle becomes longer than when it is set to "normal mode". When set to “”, the cruising range of the vehicle becomes shorter than when set to “Eco mode”. Also, when the user operates the air conditioner switch to set the air conditioner to "OFF", the cruising range of the vehicle becomes longer than when the air conditioner is set to "ON". When set to "ON", the cruising range of the vehicle is shorter than when the air conditioner is set to "OFF". Further, as another example of the vehicle-mounted device 120 that changes the cruising distance of the vehicle, an accelerator pedal, a brake pedal, or the like can be given. For example, when the user tends to step on the accelerator pedal or the brake pedal excessively, the cruising range of the vehicle tends to become short. As described above, the in-vehicle device 120 includes one that affects the cruising distance of the vehicle when operated by the user, and the display control device 150 displays the operation information of the in-vehicle device 120 from the in-vehicle device 120. By receiving the information, it is possible to determine, based on the received operation information of the in-vehicle device 120, whether or not an operation that affects the cruising range of the vehicle has been performed.

The vehicle speed sensor 130 detects the traveling speed of the vehicle. For example, the vehicle speed sensor 130 can calculate the traveling speed of the vehicle from the wheel speed detected by the wheel speed sensor that detects the number of rotations of the wheel. The information on the traveling speed of the vehicle detected by the vehicle speed sensor 130 is transmitted to the display control device 150.

Fuel sensor 140 detects the remaining fuel capacity of the vehicle. The information on the remaining fuel amount detected by the fuel sensor 140 is transmitted to the display control device 150.

The display device 160 is a device for displaying information including the cruising distance of the vehicle to the user. As such a display device 160, for example, a meter display, a display of a navigation device, a display provided on an instrument panel, a head-up display, or the like can be used. In the following, a configuration using a meter display as the display device 160 will be described as an example.

The display control device 150 can access a ROM (Read Only Memory) that stores a program for controlling the display of information by the display device 160, and a CPU (Central Processing Unit) that executes the program stored in this ROM. RAM (Random Access Memory) that functions as a storage device. In addition, as an operation circuit, instead of or together with a CPU (Central Processing Unit), an MPU (Micro Processing Unit), a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), and the like. Can be used.

The display control device 150 executes a program stored in the ROM by the CPU to calculate a cruising distance of the vehicle, and a display control function for controlling display of information including the cruising distance. , Is provided. Each function of the display control device 150 will be described below.

The cruising distance calculation function of the display control device 150 calculates the fuel consumption of the vehicle based on the information on the fuel injection amount received from the engine control device 110 and the information on the traveling speed of the vehicle acquired from the vehicle speed sensor 130. The cruising distance calculating function calculates the cruising distance of the vehicle based on the calculated fuel consumption of the vehicle and the remaining fuel amount of the vehicle acquired from the fuel sensor 140.

In addition, the cruising distance calculation function determines whether or not the user has performed an operation that affects the cruising distance of the vehicle based on the operation information of the on-vehicle device 120 acquired from the on-vehicle device 120, and the user determines When it is determined that an operation that affects the cruising range is performed, the fuel consumption of the vehicle is corrected based on the operation information of the in-vehicle device 120, and the cruising range of the vehicle can be calculated based on the corrected fuel consumption. .. For example, in the cruising distance calculation function, when the user operates the eco-mode switch and obtains operation information that the "eco mode" has been set, compared to the case where the "normal mode" is set, The fuel consumption of the vehicle can be corrected to a high value. Alternatively, when the user operates the air conditioner switch and obtains the information that the air conditioner is set to “OFF”, the cruising range calculation function is compared with the case where the air conditioner is set to “ON”. The fuel consumption of the vehicle can be corrected to a high value. Furthermore, the cruising distance calculation function can correct the fuel consumption of the vehicle to a high value when the user tends to excessively depress the accelerator pedal or the brake pedal. The cruising distance calculation function can calculate the cruising distance of the vehicle by multiplying the corrected fuel consumption by the remaining fuel amount of the vehicle acquired from the fuel sensor 140.

The display control function of the display control device 150 controls the display of the information including the cruising range by the display device 160. The display control processing by the display control function will be described below with reference to FIG. FIG. 2 is a flowchart showing the display control process according to this embodiment. The display control process described below starts with the ignition turned on and is repeatedly executed by the display control device 150 until the ignition is turned off.

In step S101, the display range of the display control device 150 is used to calculate various types of information necessary for calculating the available range of the vehicle. For example, the cruising range calculation function uses the engine control device 110 to inject fuel injection amount information, the in-vehicle device 120 to operate information for the in-vehicle device 120, the vehicle speed sensor 130 to inquire about vehicle traveling speed, and the fuel sensor 140 to inject fuel. Information on the remaining capacity can be acquired.

In step S102, the current cruising distance is calculated by the cruising distance calculating function based on the various information acquired in step S101. For example, the cruising distance calculation function calculates the fuel consumption of the vehicle based on the fuel injection amount and the traveling speed information of the vehicle acquired in step S101, and calculates the calculated fuel consumption and the remaining fuel capacity acquired in step S101. Based on this, the cruising range of the vehicle can be calculated. The cruising distance calculation function can also correct the fuel consumption of the vehicle based on the operation information of the in-vehicle device 120 acquired in step S101, and calculate the cruising distance based on the corrected fuel consumption. In the present embodiment, the display control processing shown in FIG. 2 is repeatedly executed, and in the following, the latest cruising distance calculated in the current display control processing (nth display control processing) is set to the current cruising range. The available distance is defined as the available range, and the cruising range calculated in the previous display control process (n-1th display control process) is described as the previous available range.

In step S103, the display control function of the display control device 150 determines, based on the operation information of the in-vehicle device 120 acquired in step S101, whether the user has performed a predetermined operation that affects the cruising range of the vehicle. Is done. For example, the display control function is provided when the user performs an eco mode switch switching operation, a user performs an air conditioner switch on/off operation, an accelerator pedal or a brake pedal operation, and the like. It can be determined that the user has performed a predetermined operation that affects the cruising range. When it is determined that the user has performed the predetermined operation that affects the cruising distance of the vehicle, the process proceeds to step S106. On the other hand, when it is determined that the user does not perform the predetermined operation that affects the cruising range of the vehicle, the process proceeds to step S104.

In step S104, the display control function determines whether or not a predetermined time or more has elapsed since the current cruising distance calculated in step S102 is displayed. Here, if it is determined in step S103 that the user has performed a predetermined operation that affects the cruising range of the vehicle (step S103=Yes), in steps S111, S113, and S114, which will be described later, in step S102. The calculated current cruising distance is displayed on the display device 160. Then, after displaying the current cruising distance, the process returns to step S101, and after the present cruising distance is displayed, the user does not perform an operation that affects the cruising distance of the vehicle again (step S103=No). When it is determined that the predetermined time or more has passed (step S104=Yes), the process proceeds to step S115. On the other hand, after the ignition is turned on, if the user has not performed a predetermined operation that affects the cruising range of the vehicle (step S103=No), the cruising range this time is not displayed. It is not determined that the predetermined time or more has elapsed since the display of the cruising distance this time (step S104=No), and the process proceeds to step S105. In step S105, the current cruising distance calculated in step S102 is set as the previous cruising distance by the display control function. Then, the process returns to step S101.

If it is determined in step S103 that the user has performed the predetermined operation that affects the cruising range of the vehicle, the process proceeds to step S106. In step S106, the display control function determines whether or not the cruising range is displayed on the display device 160. Specifically, the display control function determines whether or not any of the current cruising distance, the transition cruising distance described later, and the previous cruising distance is displayed on the display device 160. If none of the current cruising distance, the transition cruising distance, and the previous cruising distance is displayed on the display device 160, the process proceeds to step S107. In step S107, the display control function displays a previous cruising range interrupt display (details will be described later), and then the process proceeds to step S108. On the other hand, in step S106, if any of the current cruising distance, the transition cruising distance, and the previous cruising distance is displayed on the display device 160, the process of step S107 is skipped and the process proceeds to step S108. move on.

Here, the processes of steps S101 to S107 will be described in detail with reference to FIG. FIG. 3 is a diagram for explaining a display control method in a scene in which the cruising range of the vehicle is changed by a user's operation. As shown in FIG. 3, since the meter display according to the present embodiment has a small display space for displaying information, only one of the information such as vehicle speed, fuel consumption, and cruising range can be displayed. There is. In addition, the meter display is provided with a display switching button, and the user operates the display switching button to select one of the information such as vehicle speed, fuel consumption, and cruising range, and display it on the meter display. It is possible to display. In the example shown in FIG. 3, the user has previously selected to display the fuel consumption information, and the fuel consumption information is previously displayed on the meter display (the same applies to the example shown in FIG. 4 hereinafter). ..

In the example shown in FIG. 3, at time t1, the user operates the eco mode switch to change the traveling state of the vehicle from the “normal mode” to the “eco mode”, and thus the cruising range has changed. On the other hand, at a time before time t1 (for example, time t0), since the user has not performed an operation that affects the cruising range of the vehicle after the ignition is turned on (step S103=No), the cruising range is Is not displayed, and the fuel consumption information selected by the user is still displayed. Note that the processes of steps S101 to S105 are repeatedly performed until an operation that affects the cruising distance of the vehicle is performed at time t1 (step S103=No). That is, the calculation of the current cruising distance (step S102) and the process of setting the calculated current cruising distance as the previous cruising distance (step S105) are repeated.

Then, at time t1, the user operates the eco mode switch to change the traveling state of the vehicle from the "normal mode" to the "eco mode", so that the cruising range of the vehicle changes from "500 km" to "580 km". doing. In this case, the display control function determines that the user has performed a predetermined operation that affects the cruising range of the vehicle (step S103=Yes), and determines whether the cruising range is displayed on the display device 160. It is determined (step S106). In the example shown in FIG. 3, the cruising range is not displayed on the display device 160 until the time t1 (step S106=No), and therefore the previous cruising range is interrupted (step S107). Specifically, the display control function forces the display device 160 to display the previous cruising distance instead of the currently displayed fuel consumption information. As a result, as shown in FIG. 3, at time t1, instead of the fuel consumption information “15 km/L”, the previous cruising range “500 km” is displayed on the display device 160. As the previous cruising distance displayed on the display device 160 in the display control processing of this time (nth time), the previous cruising distance set in step S105 of the display control processing of the previous time (n-1th time) is used. ..

Returning to FIG. 2, in step S108, the display control function determines whether the cruising range has changed by a predetermined value or more. Specifically, the display control function calculates the difference between the current cruising range and the previous cruising range, and when the difference between the current cruising range and the previous cruising range is greater than or equal to a predetermined value, the cruising range is calculated. Can be determined to have changed by a predetermined value or more. When it is determined that the cruising range has changed by the predetermined value or more, the process proceeds to step S109. On the other hand, if it is determined that the cruising range has not changed by the predetermined value or more, the process proceeds to step S114.

In step 109, the display control function determines whether or not the transition cruising distance calculated in the previous display control process is displayed on the display device 160. In the present embodiment, the display control process shown in FIG. 2 is repeatedly executed even after the display of the transition cruising distance is started in steps S111 and S113 described later, and after the process returns to step S101, If the user again performs a predetermined operation that affects the possible travel distance, the process may proceed to step S109 again before the display of the transitionable travel distance ends. In this case, with the transition cruising distance calculated in the previous (n-1)th display control processing being displayed on the display device 160, the process proceeds to step S109 of the current (nth) display control processing. Become. As described above, in step S109, when the transition cruising distance calculated in the previous display control process is displayed on the display device 160, the process proceeds to step S112. On the other hand, when the transitional cruising distance calculated in the previous display control process is not displayed on the display device 160, the process proceeds to step S110.

In step S110, the transition controllable distance is calculated by the display control function. Specifically, the display control function first calculates the effect variation amount A1 by dividing the difference D1 between the current cruising distance and the previous cruising distance by a predetermined variation division number N (A1=D1/ N). Then, the display control function is a distance between the current cruising distance and the previous cruising distance, and a plurality of distances at which the respective distance intervals are evenly separated by the effect variation amount A1, the transition cruising distance. Calculate as

Then, in step S111, the display control function displays the transitional cruising distance and the current cruising distance in an interrupted manner. Specifically, the display control function, following the previous cruising distance displayed in step S107, sets the plurality of transition cruising distances calculated in step S110 and the current cruising distance calculated in step S102. The display device 160 causes the display device 160 to display the values in a step-by-step manner from the side closer to the value of the possible distance.

For example, in the example shown in FIG. 3, at time t1, the user operates the eco mode switch to change the running state of the vehicle from the “normal mode” to the “eco mode”, and the cruising range of the vehicle is “ It has changed from "500 km" to "580 km". In this case, the display control function calculates the difference between the previous cruising range "500 km" and the current cruising range "580 km" as "80 km", and the difference "80 Km" is a predetermined value (shown in FIG. 3). In the example, “20 km” is set.) It is determined whether or not the value is equal to or more than that (step S108). Since the difference "80 km" between the previous cruising distance and the current cruising distance is equal to or larger than the predetermined value "20 km", the process proceeds to step S109. Note that the above-mentioned predetermined value is an example, and can be set as appropriate.

In the example shown in FIG. 3, since the transitional cruising distance is not displayed at time t1 (step S109=No), the display control function causes a plurality of transitions between the previous cruising distance and the current cruising distance. The cruising range is calculated (step S110). For example, when the variable division number N is set to "4", the display control function divides "80 km" which is the difference between the previous cruising distance and the current cruising distance by "20 km" by dividing the variable division number "4". , And as the effect variation amount A1. Then, the display control function provides a plurality of distances that are evenly separated by "20 km", which is the effect variation amount A1, between the previous cruising distance "500 km" and the current cruising distance "580 km". , Transition cruising distance is calculated (step S110). In this case, the display control function can calculate three transition cruising distances of “520 km”, “540 km”, and “560 km”. The variable division number described above is an example, and can be set as appropriate.

Then, the display control function performs an interrupt display of the calculated transitional cruising distance and the calculated current cruising distance (step S111). In the example shown in FIG. 3, the previous cruising range "500 km" is displayed at time t1 (step S107), and the display control function is configured to display a plurality of transition cruising ranges and this time from time t2 to time t6. The cruising range is displayed step by step on the display device 160, starting from the one closest to the value of the previous cruising range. For example, in the example shown in FIG. 3, the display control function displays the transitional range available distance “520 km” at time t2, the transitional range available distance “540 km” at time t3, and the transitional range available distance “at time t4. 560 km" is displayed, and the current cruising range "580 km" is displayed at time t5.

When displaying the transitional cruising distance and the current cruising range in steps S111 and S113, the display control function equalizes the previous cruising range, the transitional cruising range, and the present cruising range, as shown in FIG. It can be displayed on the display device 160 at various time intervals. For example, in the example shown in FIG. 3, from time t1 to time t6, the respective time intervals are equal, and the previous cruising distance, the transition cruising distance, and the present cruising distance are displayed at equal time intervals. It is displayed at 160. In other words, the display control function can cause the display device 160 to display the previous cruising range, each transition cruising range, and the current cruising range at the same time.

Further, when the transitional cruising distance calculated in the previous (n-1)th display control processing is displayed (step S109=Yes), the cruising distance greatly changes in the current (nth) display control processing. If so (step S108=Yes), the process proceeds to step S112.

In step S112, the display control function allows the currently displayed transitional cruising distance (transitionable cruising distance calculated in the (n-1)th display control process) and the newly calculated current cruising possible distance (nth time). A new transition cruising distance (transition cruising distance of the n-th display control processing) is calculated with the current cruising distance calculated by the display control processing. Specifically, the display control function calculates a difference D2 between the currently displayed transitional cruising distance and the newly calculated current cruising distance, and divides the calculated difference D2 by a predetermined effect division number N. Then, a new effect variation amount A2 is calculated. Then, the display control function sets a new transition range between the currently displayed transition range and the newly calculated current range that are different in distance distance by the effect variation amount A2. Calculate as possible distance.

Then, in step S113, the display control function displays an interrupt display of the transition cruising distance and the current cruising distance newly calculated in step S112. Specifically, the display control function calculates the new one calculated in step S112 in order from the one closer to the currently displayed transitional range (transitionable range calculated in the (n-1)th display control process). The transitionable range (transitionable range calculated in the nth display control process) is gradually displayed on the display device 160, and then the newly calculated current range (nth display control process). Display the current cruising distance calculated in.

Here, the processes of steps S109, S112, and S113 will be described in detail with reference to FIG. FIG. 4 is a diagram for explaining a display control method in a scene in which the cruising range of the vehicle is changed by a user operation while the transition cruising range is being displayed. In the example shown in FIG. 4, similarly to the example shown in FIG. 3, at time t11, the user operates the eco mode switch to change the traveling state of the vehicle from the “normal mode” to the “eco mode” (step (S103=Yes), the cruising range has changed from "500 km" to "580 km". As a result, it is determined that the cruising range has changed significantly (step S108=Yes), and from time t11 to time t14, the previous cruising range "500 km" and the transition cruising ranges "520 km" and "540 km" are the fuel consumption. Instead of the information, it is displayed by being interrupted by the display device 160 (steps S107 and S111).

Further, in the example shown in FIG. 4, the display control process shown in FIG. 2 is repeatedly performed while displaying the transitionable travel distance. Therefore, after the transitional cruising distance is displayed at time t12, the process proceeds to step S105, and after the current cruising range is set as the last cruising range, the process further returns to step S101 to newly start the cruising range. The distance is calculated (step S102). Then, in the example shown in FIG. 4, at time t14, the user again operates the eco mode switch to change the traveling state of the vehicle from the “eco mode” to the “normal mode”, and the cruising range starts from “580 km”. It has changed to "500 km". As a result, it is determined that the user has performed an operation that affects the cruising range of the vehicle (step S103=Yes), and the process proceeds to step S106. Further, at time t14, since the transition cruising distance “540 km” calculated in the previous display control process is displayed on the display device 160 (step S106=Yes), the process of step S107 is not performed and the process is executed. It proceeds to step S108. Here, "500 km" which is the newly calculated current cruising distance (current cruising distance calculated in the n-th display control processing) and the previous cruising distance (calculated in the (n-1)th display control processing) The difference from “580 km”, which is the current cruising distance), is greater than or equal to a predetermined value (eg, “20 km”) (step S108=Yes), and the transition calculated in the previous (n−1)th display control process Since the cruising range “540 km” is being displayed (step S109=Yes), the process proceeds to step S112 in this case.

In the example illustrated in FIG. 4, the difference D2 “40 km” between the transitional cruising distance “540 km” displayed at time t14 and the current cruising distance “500 km” is the predetermined effect division number N. By dividing by "4", a new effect variation amount A2 of "10 km" is calculated (step S112). Then, the display control function is a distance between the currently displayed transitional cruising distance “540 km” and the present cruising distance “500 km”, and the mutual distance intervals are equal to each other, the effect variation amount A2 “10 km”. The distance separated by "" is calculated as a new transition cruising distance (step S112). In this case, the display control function calculates "530 km", "520 km", and "510 km" as new transition cruising distances. Then, the display control function displays the newly calculated transitional cruising distance "530 km" at time t15, the newly calculated transitional cruising distance "520 km" at time t16, and newly calculates at time t17. The transitional cruising distance "510 km" is displayed, and the current cruising distance "500 km" newly calculated at time t18 is displayed.

As shown in FIG. 4, the display control function can be configured such that the larger the effect variation amount, the longer the time for displaying the respective transition cruising distances. For example, in the example shown in FIG. 4, the effect variation amount A1 is “20 km” from time t11 to time t14, and the effect variation amount A2 is “10 km” from time t14 to time t19. Therefore, as shown in FIG. 4, the display control function, the display time of each transition cruising distance from time t11 to time t13, longer than the display time of each transition cruising distance from time t14 to time t 19 can do.

Returning to FIG. 2, when it is determined in step S108 that the difference between the current cruising distance and the previous cruising distance is less than the predetermined value, the process proceeds to step S114. In step S114, the display control function controls to display the previous cruising distance next to the previous cruising distance without displaying the transitionable cruising distance.

Here, FIG. 5 is a diagram for explaining a display control method in a scene in which the variation amount of the cruising range due to a user operation is less than a predetermined value. In the example shown in FIG. 5, at time t21, the traveling state of the vehicle is changed from “normal mode” to “eco mode” (step S103=Yes), and the cruising range of the vehicle is changed from “500 km” to “505 km”. Is changing. In this case, "5 km", which is the difference between the previous cruising range "500 km" and the current cruising range "505 km", is less than the predetermined value (for example, "20 km") (step S108=No), so at time t21, Next to the previous cruising distance "500 km", the current cruising distance "505 km" is displayed (step S114).

Further, in the scene example shown in FIG. 5, at time t22, the running state of the vehicle is changed from the “eco mode” to the “normal mode” by the user's operation (step S103=Yes), and the cruising range is “505 km”. Has changed from "500km" to "500km". Also in this case, since the difference "5 km" between the previous cruising range "505 km" and the current cruising range "500 km" is less than the predetermined value "20 km" (step S108 = No), the previous cruising range is obtained at time t22. After the possible distance “505 km”, the current cruising distance “500 km” is displayed (step S114).

At time t6 in FIG. 3, time t19 in FIG. 4, and time t23 in FIG. 5, after the current cruising range is displayed (steps S111, S113, S114), the predetermined cruising range of the vehicle is affected. The user does not perform the operation of (step S103=No) again, and a predetermined time or more has elapsed (step S104=Yes). In this case, the display control function causes the display device 160 to display the information that was displayed before the interruption display of the cruising range instead of displaying the cruising range (step S115). For example, in the scenes shown in FIG. 3 to FIG. 5, the fuel consumption information selected by the user is displayed in advance before the interruptable display of the cruising range. Therefore, the display control function replaces the cruising range with the fuel consumption information. Is displayed on the display device 160.

As described above, in the present embodiment, a display that allows the display device 160 to display the current cruising distance, which is the currently calculated cruising distance, next to the last cruising distance, which is the previously calculated cruising distance. In the control device 150, the distance between the current cruising distance and the previous cruising distance is calculated as the transition cruising distance, and after the last cruising distance is displayed, before the current cruising distance is displayed, the transition is made. Control to display the cruising range. Thus, in the present embodiment, when the cruising range changes, the transition cruising range, which is the distance between the previous cruising range and the present cruising range, is displayed before the present cruising range is displayed. Since it is displayed, it is possible to present the user with a state in which the cruising range changes. As a result, it is possible to allow the user to appropriately understand that the cruising distance of the vehicle has changed, compared to the case where the present cruising distance is displayed instantaneously.

Further, in the present embodiment, when the user performs a predetermined operation that affects the cruising distance of the vehicle, by displaying the transition cruising distance, what kind of operation is performed, and how It is possible to allow the user to properly understand whether the cruising range changes. For example, when the user operates the eco-mode switch to set the "eco mode", the user is informed of the longer cruising range, so that the cruising range becomes longer when the "eco mode" is set. It is possible to make the user appropriately understand that it will be longer. In addition, by presenting to the user the fact that the cruising range is shortened due to excessive depression of the accelerator pedal or brake pedal, it is appropriate for the user that the cruising range is shortened due to excessive depression of the accelerator pedal or brake pedal. Can be grasped.

Further, in the present embodiment, when the difference between the current cruising distance and the previous cruising distance is less than a predetermined value, control is performed so that the transition cruising distance is not displayed (step S108=No, S114). If the transitional cruising distance is displayed stepwise until the difference between the current cruising distance and the previous cruising distance is less than a predetermined value, it may rather annoy the user. .. In the present embodiment, when the difference between the current cruising distance and the previous cruising distance is less than a predetermined value, the transition cruising distance is not displayed, which may cause such annoyance to the user. It can be effectively prevented.

Further, in the present embodiment, a plurality of different distances from the current cruising distance to the previous cruising distance are calculated as a plurality of transition cruising distances, and the plurality of transition cruising distances are the values of the previous cruising distance. The display device 160 causes the display device 160 to display the data in a step-by-step manner. Further, in the present embodiment, the transition cruising distance is calculated so that the intervals between the plurality of transition cruising distances are equal. In this way, by displaying the plurality of transition cruising distances on the display device 160 step by step in order from the one closer to the previous cruising distance so that the intervals between the plurality of transition cruising distances are equal, The fact that the cruising range has changed can be presented to the user in a manner that makes it easier for the user to understand. In particular, in the present embodiment, the value of the cruising range displayed on the display device 160 changes a plurality of times, so that the cruising range displayed on the display device 160 changes only once. (Compared to the case where the current cruising distance is displayed instantaneously next to the previous cruising distance), the user can appropriately understand that the cruising distance is changing. When the current cruising distance is displayed next to the previous cruising distance, the user knows that the cruising distance has changed when the difference between the previous cruising distance and the current cruising distance is relatively small. It was difficult to do. However, in the present embodiment, by changing the cruising range displayed on the display device 160 in a stepwise manner, the cruising range changes even if the difference between the previous cruising range and the current cruising range is relatively small. This makes it easy for the user to understand this.

In addition, in the present embodiment, even when the display device 160 does not display the cruising range and the display device 160 displays other data (for example, fuel consumption information in the examples shown in FIGS. 3 to 5). When the cruising distance of the vehicle changes, the previous cruising distance, the transition cruising distance and the present cruising distance are interrupted and displayed on the display device 160. As a result, even when the display space of the display device 160 is limited as in the meter display shown in FIGS. 3 to 5, it is possible to display the information on the cruising range on the display device 160, and thus the cruising range of the vehicle can be improved. It is possible for the user to appropriately recognize that the possible distance has changed.

Further, in the present embodiment, the cruising range is repeatedly calculated even while the transition cruising range is displayed, and when the cruising range changes while the transition cruising range is displayed (step S108= Yes, S109=Yes), the currently displayed transitional cruising distance (transitionable cruising distance calculated in the (n-1)th display control processing) and the newly calculated current cruising distance (in the nth display control processing) Before calculating the newly calculated current cruising distance by newly calculating the transitional cruising distance (calculated by the n-th display control process) with respect to the calculated current cruising distance, Control is performed to cause the display device 160 to gradually display the newly calculated transitional cruising distance. As a result, in the present embodiment, even when the cruising range changes while the transition cruising range is displayed, the user can appropriately recognize that the cruising range has newly changed.

The embodiments described above are described to facilitate understanding of the present invention, and are not described to limit the present invention. Therefore, each element disclosed in the above embodiment is intended to include all design changes and equivalents within the technical scope of the present invention.

For example, in the above-described embodiment, the case where the present invention is applied to an engine vehicle has been described as an example, but the present invention is not limited to this configuration, and the present invention can be applied to, for example, an electric vehicle or a hybrid vehicle. In this case, in an electric vehicle, a drive control device that controls the operation of an electric motor is used.In a hybrid vehicle, a drive control device that performs control including torque distribution between an internal combustion engine and an electric motor is used. It can be used instead of the device 110. Such a drive control device receives battery information such as the voltage value of the battery and the charging/discharging current value of the battery from the battery sensor, and calculates the remaining battery capacity based on the received voltage value of the battery and charging/discharging current value of the battery. At the same time as the calculation, battery information such as the voltage value of the battery, the charging/discharging current value of the battery, and the calculated remaining battery capacity is transmitted to the display control device 150. Then, the display control device 150 can calculate the electric power cost of the vehicle based on the battery information acquired from the drive control device, and can calculate the cruising range of the vehicle based on the calculated electric power cost. Further, the display control device 150 can also calculate the cruising range by correcting the electricity cost of the vehicle in consideration of the operation information of the in-vehicle device 120. For example, the display control device 150 calculates an acquisition tendency of regenerative electric power based on the operation information of the user's accelerator pedal or brake pedal, and based on such an acquisition tendency of regenerative electric power, the power consumption of the vehicle driven by the user. Can be corrected, and the cruising range of the vehicle can be calculated based on the corrected electricity cost.

Then, the display control device 150 can perform the display control of the cruising range also in the case of the electric vehicle or the hybrid vehicle, similarly to the engine vehicle. That is, if the difference between the current cruising distance calculated based on the battery information and the previous cruising distance is greater than or equal to a predetermined value, the display control device 150 calculates a plurality of transitional cruising distances to enable the current cruising range. Before displaying the distance, it is possible to display a plurality of transitional cruising distances on the display device 160 step by step. As a result, even in an electric vehicle or a hybrid vehicle, it is possible for the user to appropriately recognize that the cruising range has changed. For example, if regenerative power is generated by the user's operation of the accelerator pedal or brake pedal and the cruising range becomes longer, regenerative power is generated by the user's operation of the accelerator pedal or brake pedal, and the cruising range becomes longer. It is possible to make the user properly understand that.

Further, in the above-described embodiment, the configuration has been described as an example in which the information on the cruising range is displayed by interruption when the information on the fuel consumption is displayed on the display device 160, but the present invention is not limited to this configuration and the display device When 160 has a sufficient display space, it is possible to display the information on the cruising range in addition to the information such as the fuel consumption information.

The display device 160 according to the above-described embodiment corresponds to the display device of the present invention.

100... In-vehicle device 110... Drive control device 120... In-vehicle device 130... Vehicle speed sensor 140... Fuel sensor 150... Display control device 160... Display device

Claims (8)

A display control method that repeatedly calculates the cruising range and then displays the current cruising range, which is the cruising range calculated this time, next to the previous cruising range, which is the previously calculated cruising range. There
When the user performs a predetermined operation,
The distance between the current cruising distance and the previous cruising distance is calculated as the transition cruising distance,
Before displaying the cruising distance now have row transition display control for displaying the transition cruising distance,
A display control method in which the transition display control is not performed when the user does not perform the predetermined operation . The display control method according to claim 1 , wherein
A display control method in which the transition display control is not executed when the difference between the current cruising distance and the previous cruising distance is less than a predetermined value even when the user performs the predetermined operation. The display control method according to claim 1, wherein
A display control method in which the transition display control is not executed when the difference between the current cruising distance and the previous cruising distance is less than a predetermined value. A display control method according to any one of claims 1 to 3
In the transition display control, a plurality of different distances from the current cruising range to the previous cruising range are calculated as a plurality of the transition cruising ranges, and the plurality of transition cruising ranges are calculated as the previous cruising range. A display control method in which the values are displayed step by step starting from the one closest to the value of the possible distance. The display control method according to claim 4 , wherein
A display control method wherein the intervals between the plurality of transition cruising distances are equal. A display control method according to any one of claims 1 to 5
In the case where the display device does not display the cruising range and displays information different from the cruising range, in the case of executing the transition display control, in addition to the information, or, A display control method for displaying the transition cruising distance instead of the information. A display control method according to any one of claims 1 to 6
While the transitional range is displayed, the range is calculated repeatedly,
When the cruising range changes while the transition cruising range is being displayed, the distance between the transition cruising range being displayed and the newly calculated cruising range is set to a new value. A display control method for displaying the new transition cruising distance before displaying the newly calculated current cruising distance, which is calculated as the transition cruising distance. A display control device capable of repeatedly calculating the cruising range, and displaying the present cruising range, which is the cruising range calculated this time, next to the previous cruising range, which is the previously calculated cruising range. And
When the user performs a predetermined operation,
The distance between the current cruising distance and the previous cruising distance is calculated as the transition cruising distance,
Before displaying the current cruising distance , perform transition display control for displaying the transition cruising distance ,
Wherein when the user has not performed the predetermined operation, the transition display control has a display control apparatus to perform.

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