JP2023055710A - Stimulation control device, stimulation control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stimulation control device capable of generating a stimulation according to the timing suitable for arousing a user.

SOLUTION: A stimulation control device includes living body information acquisition means that acquires living body information on a user, numerical value generation means that generates a numerical value on the basis of the living body information, initiation instruction means that instructs stimulation means, which stimulates the user when the numerical value exceeds a first threshold, to initiate a stimulation, cease instruction acquisition means that acquires a cease instruction for the stimulation which is issued from the user to the stimulation means, and setting means that sets the first threshold on the basis of the numerical value obtained when the cease instruction is acquired.

SELECTED DRAWING: Figure 3

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to a stimulus control device, a stimulus control method, and a program.

2. Description of the Related Art In order to prevent a driver of an automobile from falling asleep, an awakening assistance device is known that assists the awakening of the driver by emitting a warning sound or the like.

Such a wake-up support device asks the driver if he/she desires wake-up support when the degree of drowsiness of the driver reaches a standard, and when the driver answers that he/she desires wake-up support, wake-up support is performed. An assisting device is disclosed in US Pat.

Japanese Patent No. 5375571

The awakening support device of Patent Document 1 does not support awakening until an answer is obtained from the driver. For this reason, one example of the problem is that if the driver does not answer for some reason, the driver's awakening cannot be assisted.

Further, Patent Literature 1 discloses that awakening support is started without waiting for an answer from the driver when a strong degree of drowsiness is detected. However, under such circumstances, one of the problems is that it takes time to wake up the driver because he/she is already very sleepy.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stimulus control apparatus capable of generating stimuli at appropriate timings for awakening of the user.

The stimulation control device according to claim 1 of the present application comprises biological information acquiring means for acquiring biological information of a user, numerical value generating means for generating a numerical value based on the biological information, and the numerical value exceeding a first threshold value. start instructing means for instructing stimulation means for stimulating the user to start stimulation, stop instruction acquisition means for acquiring a stop instruction for the stimulation from the user to the stimulation means, and the stop setting means for setting the first threshold based on the numerical value when the instruction is acquired.

A stimulus control method according to claim 11 of the present application is a stimulus control method executed by a stimulus control device that controls stimulus means for stimulating a user, the method comprising: acquiring biological information of the user; generating a numerical value based on; instructing the stimulation means to initiate stimulation when the numerical value exceeds a first threshold; and terminating the stimulation from the user to the stimulation means. and setting the first threshold based on the numerical value when the stop instruction is obtained.

The program according to claim 12 of the present application is provided in a computer, the step of acquiring biometric information of a user, the step of generating a numerical value based on the biometric information, and the step of generating the numerical value when the numerical value exceeds a first threshold value. a step of instructing a stimulation means for stimulating a user to start stimulation; a step of obtaining an instruction from the user to stop the stimulation to the stimulation means; and setting the first threshold based on.

The recording medium according to claim 13 of the present application provides a computer with a step of acquiring biometric information of a user, a step of generating a numerical value based on the biometric information, and a step of generating a numerical value based on the biological information; a step of instructing a stimulation means for stimulating the user to start stimulation; a step of obtaining an instruction to stop the stimulation from the user to the stimulation means; and the numerical value when the stop instruction is obtained. and a step of setting the first threshold value based on .

1 is a functional block diagram of a stimulus control device according to Example 1. FIG. FIG. 4 is an explanatory diagram showing an example of a threshold DB table stored in a storage unit; FIG. 4 is a flowchart showing processing by the stimulus control device according to Example 1; FIG. 4 is an explanatory diagram showing an example of a threshold DB table stored in a storage unit; FIG. 11 is a flowchart showing processing by the stimulus control device according to Example 2; FIG. 11 is a flowchart showing processing by a stimulus control device according to a modification of Example 2; FIG. 11 is a flowchart showing processing by the stimulus control device according to Example 3; FIG. 4 is an explanatory diagram showing an example of a threshold DB table stored in a storage unit; FIG. 4 is an explanatory diagram showing an example of a threshold DB table stored in a storage unit; FIG. 11 is a flowchart showing processing by a stimulus control device according to Example 5; FIG. 11 is a flowchart showing processing by a stimulus control device according to Example 6; FIG. 4 is an explanatory diagram showing an example of a threshold DB table stored in a storage unit;

The stimulus control device 10 of Example 1 will be described below.

The stimulus control device 10 is mounted on a moving object such as an automobile. The mobile body may be a mobile body other than an automobile, such as a bicycle, a motorcycle, or an airplane. In this embodiment, a case where the stimulus control device is installed in an automobile, which is an example of a moving body, will be described.

FIG. 1 shows functional blocks of a stimulus control device 10 according to the first embodiment.

The input unit 20 is an interface unit connected so as to be able to acquire data from the biosensor BS and the display device DS. The stimulation control device 10 receives data from the biosensor BS and the display device DS via the input 20 .

The biosensor BS is a sensor that acquires biometric information of a driver who drives an automobile, that is, a user. The biosensor BS is communicably connected to the stimulation control device 10 by wire or wirelessly. The biological information includes, for example, the driver's body temperature, pulse per predetermined time, blood pressure, breathing rate per predetermined time, number of blinks per predetermined time, number of yawns per predetermined time, and the like.

The biosensor BS is any device that measures these biometric information. For example, when measuring the pulse of the driver, the biosensor BS is a pulse meter with pulse measurement function. When measuring the driver's blood pressure, the biosensor BS is a sphygmomanometer with a blood pressure measurement function. When measuring the driver's respiration rate, the biosensor BS is a measuring device that measures the up-and-down motion of the driver's chest wall photographed by a camera. When measuring the number of blinks of the driver, the biosensor BS is a measuring device that measures the vertical movement of the driver's eyelids photographed by a camera. These devices may be devices installed in the automobile or wearable devices worn by the driver.

The display device DS is, for example, a display provided in the center console of an automobile. The display device DS is a touch panel display that allows the driver to input arbitrary information to the stimulus control device 10 . Note that the input device is not limited to the display device DS as long as it is possible to input arbitrary information to the stimulus control device 10. For example, an input device such as a keyboard may be used.

The output section 22 is an interface section connected to the vibration generator VB. The stimulation control device 10 can control the start and stop of vibration of the vibration generator VB.

The vibration generator VB gives the driver vibration, which is a stimulus for awakening, in accordance with an instruction from the stimulus control device 10 . In other words, the vibration generator VB functions as stimulus means for urging the driver to wake up. The vibration generator VB is built in, for example, a driver's seat of an automobile.

The storage device 23 is configured by, for example, a hard disk device, SSD (Solid State Drive), flash memory, or the like. The storage device 23 stores various programs such as BIOS (Basic Input Output System) and software.

Further, information for generating information on the degree of drowsiness of the driver from the biometric information and a first threshold value of the degree of drowsiness of the driver for starting vibration generation from the vibration generator VB (hereinafter referred to as the first threshold). can be stored. Specifically, the storage device 23 can store a threshold DB (Data Base) in which the first threshold is recorded for each driver.

The control unit 24 is implemented by a computer having a CPU (Central Processing Unit) 24a as an arithmetic processing unit, a ROM (Read Only Memory) 24b as a main storage device, and a RAM (Random Access Memory) 24c. The CPU 24a reads a program corresponding to the processing content from the ROM 24b or the storage device 23, develops it in the RAM 24c, and cooperates with the developed program to realize various functions.

Input section 20 , output section 22 , storage device 23 and control section 24 are connected to each other via system bus 25 .

The control unit 24 can acquire the biological information of the driver received via the input unit 20 . The control unit 24 can acquire a stimulus stop instruction from the driver to the vibration generator VB. Specifically, the control unit 24 can acquire a stop instruction input from the display device DS via the input unit 20 .

The control unit 24 can generate values such as numerical values based on the biometric information received via the input unit 20 . Specifically, the control unit 24 can generate a numerical value regarding the degree of drowsiness of the driver based on the driver's biological information. Hereinafter, the numerical value generated by the control unit 24 is simply referred to as the drowsiness degree value.

The control unit 24 can instruct the vibration generator VB to start stimulation when the drowsiness degree value exceeds the first threshold. Specifically, the control unit 24 transmits a signal instructing the start of stimulation to the vibration generator VB via the output unit 22 .

The control unit 24 can set the first threshold value based on the drowsiness degree value of the driver when the stop instruction is acquired. Specifically, the control unit 24 sets the threshold value stored in the storage unit 23 based on the drowsiness degree value when the stop instruction information for stopping the vibration of the vibration generator VB input through the display device DS is acquired. The first threshold stored in the DB is updated and set.

The control unit 24 can identify one driver from a plurality of drivers. That is, the control unit 24 sets the first threshold value for each driver based on the drowsiness degree value when the stop instruction is acquired.

FIG. 2 shows an example of a threshold DB table stored in the storage unit 23. As shown in FIG. When the drowsiness degree value of the driver of the automobile exceeds the first threshold value, the control unit 24 transmits a vibration start instruction to the vibration generator VB. As shown in FIG. 2, the initial setting (initial value) of the first threshold value is set to "6" for the degree of drowsiness of the driver. In addition, in the present embodiment and subsequent embodiments, the drowsiness degree value is a numerical value in 10 stages. The closer the drowsiness level value is to "10", the lower the wakefulness of the driver. In addition, the closer the drowsiness level value is to "1", the more alert the driver is.

When the driver performs an operation to stop the vibration of vibration generator VB, control unit 24 receives a stop instruction. The control unit 24 sets the first threshold value based on the drowsiness degree value when the stop instruction is received.

For example, when the first threshold value is set to "6" and the assumed drowsiness level value at the time of acquisition of the stop instruction is set to "3", the control unit 24, when the expected result is obtained, Make settings to maintain state.

Further, when the drowsiness level value of the driver when the stop instruction is acquired is "5" or "4", it is considered that the driver is more alert than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold higher. Specifically, the control unit 24 sets the first threshold value to "8" when the drowsiness degree value at the time of acquisition of the stop instruction is "5". Further, the control unit 24 sets the first threshold value to "7" when the drowsiness level value at the time of acquisition of the stop instruction is "4".

Furthermore, when the drowsiness degree value of the driver when the stop instruction is obtained is "1" or "2", it is considered that the driver is in a state of being more sleepy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold to be low. Specifically, the control unit 24 sets the first threshold value to "4" when the drowsiness level value at the time of acquisition of the stop instruction is "1". Further, the control unit 24 sets the first threshold value to "5" when the drowsiness level value at the time of acquisition of the stop instruction is "2".

Note that the control unit 24 sets the first threshold value for generating the vibration of the vibration generator VB for each driver. Identification of the driver is not particularly limited, and may be performed, for example, by reading a storage medium storing driver information. Specifically, driver information may be read from an IC (integrated circuit) chip embedded in the card. Alternatively, one or a plurality of drivers may be stored in the storage unit 23 in advance, and the registered driver information may be read out from the storage unit 23 by the user operating the display device DS.

FIG. 3 shows the processing flow of the control unit 24. As shown in FIG. As shown in FIG. 3, the control unit 24 acquires biometric information from the biosensor BS (step S101). In step S101, the control unit 24 functions as biometric information acquiring means for acquiring biometric information of the driver. Note that the control unit 24 may acquire the biometric information at predetermined time intervals and store the acquired biometric information in the storage unit 23 sequentially.

The control unit 24 generates a drowsiness degree value based on the biological information acquired in step S101 (step S102). At step S102, the control unit 24 functions as a numerical value generating means for generating numerical values based on the biometric information.

The control unit 24 determines whether the drowsiness degree value generated in step S102 exceeds the first threshold (step S103).

When the control unit 24 determines in step S103 that the drowsiness level value does not exceed the first threshold value (step S103: N), the control unit 24 acquires biological information again (step S101) and generates a drowsiness level value ( Step S102), it is determined whether the generated drowsiness level value exceeds the first threshold (step S103).

In the judgment in step S103, if the control unit 24 judges that the drowsiness degree value exceeds the first threshold (step S103: Y), it transmits a start instruction to start stimulation to the vibration generator VB (step S104). ). In step S104, the control unit 24 functions as stimulation means for stimulating the driver when the numerical value exceeds the first threshold, that is, start instruction means for instructing the vibration generator VB to start stimulation (vibration). .

When the driver inputs a stop instruction to stop the vibration of the vibration generator VB from the display device DS, the stop instruction is transmitted from the display device DS.

The control unit 24 determines whether or not the stop instruction transmitted from the display device DS has been acquired (step S105). In step S105, the control unit 24 functions as stop instruction acquisition means for acquiring a vibration stop instruction from the driver to the vibration generator VB. When the control unit 24 determines in step S105 that the stop instruction has been acquired (step S105: Y), the control unit 24 acquires the biological information of the driver when the stop instruction was acquired (step S106), and stores the biological information acquired in step S106. A drowsiness degree value is generated based on the information (step S107). The control unit 24 sets the first threshold based on the drowsiness degree value generated in step S107 (step S108). In step S108, the control unit 24 functions as setting means for setting the first threshold value based on the drowsiness degree value when the stop instruction is received.

Note that the determination in step S105 is repeated until a stop instruction is acquired (step S105: N).

The drowsiness degree value generated in step S107 may be stored in the storage unit 23 each time the drowsiness degree value generation process in step S107 is performed. In this case, the control unit 24 acquires the drowsiness degree values when the stop instruction is acquired a plurality of times, and sets the first threshold value based on the drowsiness degree values acquired a plurality of times. may

Specifically, for example, the control unit 24 calculates the average value of the drowsiness level values generated by the most recent four times of the drowsiness level value generation processing in step S107, and based on the calculated average value, 1 threshold may be set. Further, for example, the control unit 24 may calculate an average value of all drowsiness level values generated in step S107, and set the first threshold value based on the calculated average value. Furthermore, for example, the control unit 24 extracts any plurality of drowsiness degree values from among the drowsiness degree values generated in step S107, calculates an average value, and calculates the first threshold value based on the calculated average value. may be set. Further, for example, the control unit 24 may set the first threshold based on the moving average of the drowsiness degree values generated in step S107.

Moreover, in this example, a vibration generator VB was used as the stimulation means. However, the stimulation means is not limited to the vibration generator, and may be, for example, a speaker that outputs sound. Alternatively, an air conditioner mounted on a moving object may be used as another stimulation means. For example, the driver may be stimulated by lowering the temperature inside the vehicle. Alternatively, the driver may be stimulated by blowing cool air from an air conditioner onto the driver's face. Furthermore, the driver may be stimulated by outputting a scent with a high awakening effect such as mint.

Furthermore, in this embodiment, the control unit 24 generates the drowsiness level value based on the driver's biological information. When the generated drowsiness degree value exceeds the first threshold, the control unit 24 transmits a start instruction to generate vibration to the vibration generator VB. However, the control unit 24 may transmit a start instruction to the vibration generator VB to generate vibration based on the biological information of the driver without generating the drowsiness degree value. For example, the control unit 24 may transmit a start instruction to generate vibration to the vibration generator VB when numerical values such as the driver's heart rate, breathing rate, and blood pressure exceed thresholds.

As described above, according to the stimulus control apparatus according to the present embodiment, when the driver performs the operation to stop the vibration generator VB, that is, when the driver acquires the stop instruction, based on the drowsiness degree value, Set the drowsiness level value threshold at which the VB starts to vibrate. Therefore, it is possible to generate stimulation in a state suitable for the user.

That is, the drowsiness level value when the vibration generator VB is stopped indicates that the driver is definitely awake. It is presumed that the drowsiness level value of the driver at this time has little variation and that a constant value can be obtained. By setting the first threshold value based on such a constant drowsiness degree value, it is possible to generate stimulation in a state appropriate for the user.

A stimulus control device 10 of Example 2 will be described. The stimulus control apparatus 10 of Example 1 sets the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started, that is, the first threshold value, based on the drowsiness degree value when the stop instruction is acquired. The stimulation control device 10 of the second embodiment sets a threshold of the drowsiness degree value for stopping the stimulation of the vibration generator VB, i.e., the second threshold, based on the drowsiness degree value when the driver performs the stop operation of the vibration generator VB. is different from the stimulus control device 10 of the first embodiment in that . It should be noted that the same reference numerals are given to the same configurations as in the first embodiment, and the description thereof will be omitted.

The control unit 24 causes the vibration generator VB to stop vibrating when the drowsiness level value of the driver exceeds a second threshold (hereinafter referred to as a second threshold) for stopping the stimulation of the vibration generator VB. It is possible to give instructions. The control unit 24 sets the second threshold according to the drowsiness degree value of the driver when the stop instruction is acquired.

FIG. 4 shows an example of a threshold DB table stored in the storage unit 23. As shown in FIG. When the driver performs an operation to stop the vibration of vibration generator VB, control unit 24 receives a stop instruction. The control unit 24 sets the first threshold and the second threshold based on the drowsiness degree value when the stop instruction is received.

As shown in FIG. 4, for example, a case where the first threshold is set to "6" and the second threshold is set to "3" will be described. When the expected result is obtained, that is, when the drowsiness level value is "3" when the stop instruction is received, the control unit 24 performs setting to maintain the setting state.

Further, when the drowsiness level value of the driver when the stop instruction is acquired is "5" or "4", it is considered that the driver is more alert than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, the control unit 24 sets the first threshold to "8" and the second threshold to "5" when the drowsiness degree value at the time of acquisition of the stop instruction is "5". Further, when the drowsiness degree value at the time of acquisition of the stop instruction is "4", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

Furthermore, when the drowsiness degree value of the driver when the stop instruction is obtained is "1" or "2", it is considered that the driver is in a state of being more sleepy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, the control unit 24 sets the first threshold to "4" and the second threshold to "1" when the drowsiness degree value at the time of acquisition of the stop instruction is "1". Further, when the drowsiness level value at the time of acquisition of the stop instruction is "2", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

FIG. 5 shows the processing flow of the control unit 24. As shown in FIG. Note that the processing of steps S201 to S207 is the same as the processing of steps S101 to S107 described with reference to FIG. 3, so description thereof will be omitted.

As shown in FIG. 5, the control unit 24 sets the first threshold value and the second threshold value based on the drowsiness degree value when the stop instruction is received (step S208).

As described above, according to the stimulus control apparatus according to the present embodiment, when the driver performs the operation to stop the vibration generator VB, that is, when the driver acquires the stop instruction, based on the drowsiness degree value, Set the drowsiness level value threshold at which the VB starts to vibrate. Therefore, it is possible to generate stimulation in a state suitable for the user.

Further, according to the stimulus control device of the present embodiment, the threshold of the drowsiness degree value for stopping the stimulation of the vibration generator VB is set based on the drowsiness degree value when the driver performs the stop operation of the vibration generator VB. do. Therefore, the vibration of the vibration generator VB can be stopped while the driver is in an optimal wakeful state. Therefore, it is possible to optimize the feeling of use of the driver.
[Modification]
In Example 2, the control unit 24 set the second threshold. The control unit 24 may transmit a stop instruction to the vibration generator VB based on the set second threshold.

FIG. 6 shows the processing flow of the control unit 24. As shown in FIG. Note that the processing of steps S301 to S304 is the same as the processing of steps S101 to S104 described with reference to FIG. 3, so description thereof will be omitted.

As shown in FIG. 6, the control unit 24 acquires biological information (step S305), and generates a drowsiness degree value based on the biological information acquired in step S305 (step S306).

The control unit 24 determines whether the drowsiness degree value generated in step S306 is below the second threshold (step S307). If the controller 24 determines in step S307 that the drowsiness degree value generated in step S306 is not below the second threshold (step S307: N), it determines whether a stop instruction has been obtained (step S308). .

In the judgment of step S308, if the control unit 24 judges that the stop instruction has been acquired (step S308: Y), it acquires the biometric information when the stop instruction was acquired (step S309). The control unit 24 generates a drowsiness degree value based on the biological information acquired in step S309 (step S310), and sets a first threshold value and a second threshold value based on the drowsiness degree value (step S311).

If the control unit 24 determines in step S308 that the stop instruction has not been acquired (step S308: N), it returns to the process of acquiring biometric information in step S305.

In the judgment of step S307, if the control unit 24 judges that the drowsiness degree value generated in step S306 exceeds the second threshold value (step S307: Y), it instructs the vibration generator VB to stop the vibration. Send (step S312). In step S312, the control unit 24 functions as stop instruction means for instructing the vibration generator VB to stop stimulation when the drowsiness degree value exceeds the second threshold.

In this manner, the control unit 24 transmits a stop instruction to the vibration generator VB when the drowsiness level value of the driver falls below the second threshold. Therefore, since the vibration of the vibration generator VB can be stopped without the driver performing a stop operation, it is possible to improve the user's convenience.

A stimulus control device 10 of Example 3 will be described. The stimulus control apparatus 10 of Example 1 sets the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started, that is, the first threshold value, based on the drowsiness degree value when the stop instruction is acquired. The stimulus control device 10 of Example 3 differs from the stimulus control device 10 of Example 1 in that the first threshold is set based on the drowsiness degree value when the driver performs an operation to start the vibration of the vibration generator VB. different.

The control unit 24 can acquire a vibration start instruction from the driver to the vibration generator VB. Specifically, the control unit 24 can acquire the start instruction input from the display device DS via the input unit 20 .

The control unit 24 sets the threshold value of the drowsiness degree value for starting the stimulation of the vibration generator VB based on the drowsiness degree value when the driver performs the start operation of the vibration generator VB, that is, when the start instruction is acquired. set.

FIG. 7 shows the processing flow of the control unit 24. As shown in FIG. As shown in FIG. 7, the control unit 24 acquires biometric information from the biosensor BS (step S401), and generates a drowsiness degree value based on the biometric information acquired in step S401 (step S402).

The control unit 24 determines whether a start instruction has been acquired (step S403). In step S403, the control unit 24 functions as a start instruction acquisition unit that acquires a vibration start instruction for the vibration generator VB by the driver. If the control unit 24 determines in step S403 that the start instruction has been acquired (step S403: Y), the control unit 24 sets the first threshold and the second threshold based on the biometric information when the start instruction was acquired (step S404).

If the controller 24 determines in step S403 that the start instruction has not been acquired (step S403: N), it determines whether the drowsiness degree value generated in step S402 exceeds the first threshold (step S405). ). The subsequent processing of steps S406 to S414 corresponds to steps S304 to S312 of FIG. 6, so description thereof will be omitted.

As described above, according to the stimulus control device 10 according to the present embodiment, vibration is generated based on the drowsiness degree value when the driver performs the stop operation of the vibration generator VB, that is, when the stop instruction is obtained. A threshold for the drowsiness degree value at which to start vibrating the device VB, ie the first threshold, is set. Therefore, it is possible to generate stimulation in a state suitable for the user.

Also, based on the drowsiness degree value when the driver performs an operation to start the vibration of the vibration generator VB, that is, when the start instruction is obtained, the threshold value of the drowsiness degree value for starting the vibration of the vibration generator VB is set. do. That is, according to the stimulus control device 10 of the present embodiment, it is possible to set the drowsiness degree value when the driver needs assistance for awakening as the first threshold. Therefore, it is possible to generate stimulation in a state suitable for the user.

Note that the second threshold value for stopping the vibration of the vibration generator VB may be set based on the drowsiness degree value when the start instruction is acquired. In this case, the control unit 24 transmits a stop instruction to the vibration generator VB when the drowsiness level value of the driver falls below the second threshold. Therefore, since the vibration of the vibration generator VB can be stopped without the driver performing a stop operation, it is possible to improve the user's convenience.

A stimulus control device of Example 4 will be described. The stimulus control apparatus 10 of Example 1 sets the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started, that is, the first threshold value, based on the drowsiness degree value when the stop instruction is acquired. The stimulus control device 10 of Example 4 differs from the stimulus control device 10 of Example 1 in that the first threshold is set in consideration of the intensity of the stimulus of the vibration generator VB.

The control unit 24 can set at least one of the first threshold and the threshold of the drowsiness degree value for stopping the vibration of the vibration generator VB, that is, the second threshold, according to the intensity of the vibration of the vibration generator VB. be.

FIG. 8 shows an example of a threshold DB table stored in the storage unit 23. As shown in FIG. When the driver performs an operation to stop the vibration of the vibration generator VB, the control unit 24 acquires a stop instruction. The control unit 24 sets the first threshold and the second threshold based on the drowsiness degree value when the stop instruction is acquired.

As shown in FIG. 8, for example, a case where the first threshold is set to "6" and the second threshold is set to "3" will be described. When the stimulus intensity is "medium", the control unit 24 changes the setting state when expected results are obtained, that is, when the drowsiness degree value when the stop instruction is received is "3". Make settings to keep.

When the stimulus intensity is "medium" and the driver's drowsiness level value at the time of acquisition of the stop instruction is "5" or "4", it is considered that the driver is more alert than expected. . That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, the control unit 24 sets the first threshold to "8" and the second threshold to "5" when the drowsiness degree value at the time of acquisition of the stop instruction is "5". Further, when the drowsiness degree value at the time of acquisition of the stop instruction is "4", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

Furthermore, when the stimulus intensity is "medium" and the drowsiness level value of the driver at the time of acquisition of the stop instruction is "1" or "2", the driver is more drowsy than expected. It is believed that there is. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, the control unit 24 sets the first threshold to "4" and the second threshold to "1" when the drowsiness degree value at the time of acquisition of the stop instruction is "1". Further, when the drowsiness level value at the time of acquisition of the stop instruction is "2", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

When the stimulus intensity is "weak", the control unit 24 changes the setting state when expected results are obtained, that is, when the drowsiness degree value when the stop instruction is received is "2". Make settings to keep.

When the stimulus intensity is "weak" and the drowsiness degree value of the driver when the stop instruction is acquired is "5" to "3", it is considered that the driver is more alert than expected. . That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, the control unit 24 sets the first threshold to "9" and the second threshold to "6" when the drowsiness level value at the time of acquisition of the stop instruction is "5". Further, when the drowsiness degree value at the time of acquisition of the stop instruction is "4", the control unit 24 sets the first threshold to "8" and the second threshold to "5". Further, when the drowsiness degree value at the time of acquisition of the stop instruction is "3", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

If the stimulus intensity is "weak" and the drowsiness degree value of the driver when the stop instruction is obtained is "1", it is considered that the driver is more drowsy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, the control unit 24 sets the first threshold to "5" and the second threshold to "2" when the drowsiness level value at the time of acquisition of the stop instruction is "1".

When the stimulus intensity is "strong", the control unit 24 changes the setting state when expected results are obtained, that is, when the drowsiness degree value when the stop instruction is received is "4". Make settings to keep.

If the stimulus intensity is "strong" and the drowsiness degree value of the driver at the time of acquisition of the stop instruction is "5", it is considered that the driver is more awake than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, the control unit 24 sets the first threshold to "7" and the second threshold to "4" when the drowsiness degree value at the time of acquisition of the stop instruction is "5".

If the stimulus intensity is "strong" and the driver's drowsiness degree value at the time of acquisition of the stop instruction is "1" to "3", it is determined that the driver is in a state of being more drowsy than the assumed state. Conceivable. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, the control unit 24 sets the first threshold to "3" and the second threshold to "1" when the drowsiness degree value at the time of acquisition of the stop instruction is "1". Further, when the drowsiness degree value at the time of acquisition of the stop instruction is "2", the control unit 24 sets the first threshold to "4" and the second threshold to "1". Furthermore, when the drowsiness degree value at the time of acquisition of the stop instruction is "3", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

As described above, according to the stimulus control device 10 according to the present embodiment, vibration is generated based on the drowsiness degree value when the driver performs the stop operation of the vibration generator VB, that is, when the stop instruction is obtained. Set a threshold drowsiness level value at which device VB will start vibrating. Therefore, it is possible to generate stimulation in a state suitable for the user.

Further, the control unit 24 sets the threshold value of the drowsiness degree value for starting the vibration of the vibration generator VB based on the intensity of the vibration of the vibration generator VB. Therefore, the control unit 24 can set the first threshold according to the intensity of vibration. Therefore, it is possible to generate stimulation in a state suitable for the user.

Furthermore, the control unit 24 transmits a stop instruction to the vibration generator VB when the drowsiness level value of the driver falls below the second threshold. Therefore, since the vibration of the vibration generator VB can be stopped without the driver performing a stop operation, it is possible to improve the user's convenience.

A stimulus control device 10 of Example 5 will be described. The stimulus control device 10 of the above-described embodiment sets the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started, that is, the first threshold value, based on the drowsiness degree value when the stop instruction or the start instruction is obtained. . The stimulus control device 10 of the fifth embodiment differs from the above implementation in that it sets the threshold value of the drowsiness degree value for starting the vibration of the vibration generator VB based on the time from when the first threshold is exceeded to when the stop instruction is obtained. It differs from the example stimulus control device 10 .

The control unit 24 can set the first threshold based on the time from when the drowsiness degree value of the driver exceeds the first threshold to when the stop instruction is obtained. Specifically, for example, the control unit 24 can acquire the time when the drowsiness level value of the driver exceeds the first threshold and the time when the stop instruction is acquired. The control unit 24 acquires the stop instruction after the drowsiness degree value of the driver exceeds the first threshold value by the difference between the time when the driver's drowsiness degree value exceeds the first threshold value from the time when the stop instruction is acquired. Get the time to

FIG. 9 shows an example of a threshold DB table stored in the storage unit 23. As shown in FIG. When the driver performs an operation to stop the vibration of vibration generator VB, control unit 24 receives a stop instruction. The control unit 24 sets the first threshold value and the vibration generator VB based on the time from when the vibration generator VB transmits the stimulation start instruction to when it acquires the stimulation stop instruction, that is, the operation time of the vibration generator VB. A second threshold is set for the drowsiness degree value at which the vibration of the is stopped.

As shown in FIG. 9, for example, the first threshold is set to "6", the second threshold is set to "3", and the operation reference time is set to "5 minutes". When the expected result is obtained, that is, when the operation time is "5 minutes", the control unit 24 performs setting to maintain the setting state.

Further, when the operation time is "3 minutes" or "4 minutes", it is considered that the driver is more awake than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, when the operation time is "3 minutes", the control unit 24 sets the first threshold to "8" and the second threshold to "5". Further, when the operation time is "4 minutes", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

Furthermore, when the operation time is "7 minutes" or "6 minutes", it is considered that the driver is more drowsy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, when the operating time is "7 minutes", the control unit 24 sets the first threshold to "4" and the second threshold to "1". Further, when the operating time is "6 minutes", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

FIG. 10 shows the processing flow of the control unit 24. As shown in FIG. Note that the processing of steps S501 to S505 is the same as the processing of steps S101 to S105 described with reference to FIG. 3, so description thereof will be omitted.

As shown in FIG. 10, the control unit 24 acquires the operation time of the vibration generator VB based on the time from when the first threshold value is exceeded to when the stop instruction is received (step S506). The control unit 24 sets the first threshold and the second threshold based on the operating time acquired in step S506 (step S507). In step S507, the control unit 24 functions as setting means for setting the first threshold based on the time from when the numerical value exceeds the first threshold to when the stop instruction is obtained.

As described above, according to the stimulus control device 10 according to the present embodiment, the drowsiness degree value for starting the vibration of the vibration generator VB is determined based on the time from when the first threshold value is exceeded to when the stop instruction is obtained. Set a threshold. Therefore, it is possible to generate stimulation in a state suitable for the user.

Further, the control unit 24 transmits a stop instruction to the vibration generator VB when the drowsiness level value of the driver exceeds the second threshold and falls below the second threshold. Therefore, since the vibration of the vibration generator VB can be stopped without the driver performing a stop operation, it is possible to improve the user's convenience.

A stimulus control device 10 of Example 6 will be described. The stimulus control device 10 of Example 5 sets the first threshold based on the threshold of the drowsiness degree value for starting the vibration of the vibration generator VB, that is, the time from when the first threshold is exceeded to when the stop instruction is obtained. . The stimulation control apparatus 10 of Example 6 differs from the stimulation control apparatus 10 of Example 5 in that the first threshold is set based on the time from acquisition of the start instruction to acquisition of the stop instruction.

The control unit 24 can acquire a vibration start instruction from the driver to the vibration generator VB. Specifically, the control unit 24 can acquire a stop instruction input from the display device DS via the input unit 20 .

The control unit 24 sets the first threshold and the threshold of the drowsiness degree value for stopping the vibration of the vibration generator VB, that is, the second threshold, based on the time from obtaining the start instruction from the driver to obtaining the stop instruction. set.

FIG. 11 shows the processing flow of the control unit 24. As shown in FIG. Note that the processing of steps S601 and S602 is the same as the processing of steps S401 and S402 described with reference to FIG. 7, so description thereof will be omitted.

As shown in FIG. 11, the control unit 24 determines whether a start instruction has been acquired (step S603). If the control unit 24 determines in step S63 that the start instruction has not been acquired (step S603: N), it determines whether the drowsiness degree value acquired in step S402 exceeds the first threshold (step S604). ).

If the controller 24 determines in step S603 that the start instruction has been obtained (step S603: Y), it transmits a vibration start instruction to the vibration generator VB (step S605).

The control unit 24 acquires biological information (step S606) and generates a drowsiness degree value (step S607). The control unit 24 determines whether the drowsiness degree value generated in step S607 exceeds the second threshold value (step S608).

If the control unit 24 determines in step S608 that the drowsiness degree value generated in step S607 does not fall below the second threshold (step S608: N), it determines whether a stop instruction has been acquired (step S609). .

If the control unit 24 determines in step S609 that the stop instruction has been obtained (step S609: Y), it obtains the operating time based on the time from when the start instruction is obtained until when the stop instruction is obtained. (Step S610). The control unit 24 sets the first threshold and the second threshold based on the operating time acquired in step S610 (step S611).

If the control unit 24 determines in step S609 that the stop instruction has not been acquired (step S609: N), it returns to the process of acquiring biometric information in step S606.

If the controller 24 determines in step S608 that the drowsiness degree value acquired in step S607 exceeds the second threshold value (step S608: Y), it instructs the vibration generator VB to stop the vibration. is transmitted (step S612).

As described above, according to the stimulus control device 10 according to the present embodiment, the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started is set based on the time from acquisition of the start instruction to acquisition of the stop instruction. do. Therefore, it is possible to generate stimulation in a state suitable for the user.

In particular, when the driver performs an operation to start the vibration of the vibration generator VB, that is, based on the time from acquisition of the start instruction by the driver to acquisition of the stop instruction, the first threshold for starting the vibration of the vibration generator VB. set. Therefore, according to the stimulus control device 10 according to the present embodiment, the first threshold can be set based on the operating time when the driver needs assistance for awakening. Therefore, it is possible to generate stimulation in a state suitable for the user.

A stimulus control device 10 of Example 7 will be described. The stimulus control device 10 of Examples 5 and 6 determines the threshold of the drowsiness degree value for starting the vibration of the vibration generator VB, that is, the time from exceeding the first threshold to obtaining the stop instruction, or from obtaining the start instruction to obtaining the stop instruction. A first threshold was set based on the time to acquisition of . The stimulus control device 10 of Example 7 differs from the stimulus control devices 10 of Examples 5 and 6 in that the first threshold is set in consideration of the strength of the stimulus of the vibration generator VB.

The control unit 24 can set at least one of the first threshold and the threshold of the drowsiness degree value for stopping the vibration of the vibration generator VB, that is, the second threshold, according to the intensity of the vibration of the vibration generator VB. be.

FIG. 12 shows an example of a threshold DB table stored in the storage unit 23. As shown in FIG. As shown in FIG. 12, for example, the first threshold is set to "6", the second threshold is set to "3", and the reference operation time is set to "5 minutes". When the stimulus intensity is "medium", the controller 24 performs setting to maintain the setting state when expected results are obtained, that is, when the operation time is "5 minutes".

When the stimulus intensity is "medium" and the operation time is "3 minutes" or "4 minutes", it is considered that the driver is more alert than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, when the operation time is "3 minutes", the control unit 24 sets the first threshold to "8" and the second threshold to "5". Further, when the operation time is "4 minutes", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

Furthermore, when the stimulus intensity is "medium" and the operation time is "7 minutes" or "6 minutes", it is considered that the driver is more drowsy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, when the operation time is "7 minutes", the control unit 24 sets the first threshold to "4" and the second threshold to "1". Further, when the operation time is "6 minutes", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

When the stimulus intensity is "weak", the control unit 24 performs setting to maintain the setting state when expected results are obtained, that is, when the operation time is "6 minutes".

When the stimulus intensity is "weak", when the operation time is "3 minutes" to "5 minutes", it is considered that the driver is more awake than the assumed state. . That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, when the operation time is "3 minutes", the control unit 24 sets the first threshold to "9" and the second threshold to "6". Further, when the operation time is "4 minutes", the control unit 24 sets the first threshold to "8" and the second threshold to "5". Further, when the operation time is "5 minutes", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

When the stimulus intensity is "weak" and the operation time is "7 minutes", it is considered that the driver is more drowsy than expected. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, when the operation time is "7 minutes", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

When the stimulus intensity is "strong", the control unit 24 performs setting to maintain the setting state when expected results are obtained, that is, when the operation time is "4 minutes".

When the stimulus intensity is "strong" and the operation time is "3 minutes", it is considered that the driver is more awake than expected. That is, the drowsiness degree value generated based on the biometric information is generated with a numerical value higher than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold higher. Specifically, when the operating time is "3 minutes", the control unit 24 sets the first threshold to "7" and the second threshold to "4".

When the stimulus intensity is "strong" and the drowsiness degree value of the driver at the time of acquisition of the stop instruction is "5 minutes" to "7 minutes", the driver is in a more drowsy state than expected. It is believed that there is. That is, the drowsiness degree value generated based on the biometric information is generated as a numerical value lower than the actual state of the driver. In this case, the control unit 24 sets the first threshold and the second threshold to be low. Specifically, when the operation time is "7 minutes", the control unit 24 sets the first threshold to "3" and the second threshold to "1". Further, when the operation time is "6 minutes", the control unit 24 sets the first threshold to "4" and the second threshold to "1". Furthermore, when the operation time is "5 minutes", the control unit 24 sets the first threshold to "5" and the second threshold to "2".

As described above, according to the stimulus control device 10 according to the present embodiment, the threshold value of the drowsiness degree value at which vibration of the vibration generator VB is started is set based on the time from acquisition of the start instruction to acquisition of the stop instruction. do. Therefore, it is possible to generate stimulation in a state suitable for the user.

Further, the control unit 24 sets the threshold value of the drowsiness degree value for starting the vibration of the vibration generator VB based on the intensity of the vibration of the vibration generator VB. Therefore, the control unit 24 can set the first threshold according to the intensity of vibration. Therefore, it is possible to generate stimulation in a state suitable for the user.

Furthermore, the control unit 24 transmits a stop instruction to the vibration generator VB when the drowsiness level value of the driver falls below the second threshold. Therefore, since the vibration of the vibration generator VB can be stopped without the driver performing a stop operation, it is possible to improve the user's convenience.

10 stimulation control device 24 control unit VB vibration generator

Claims (1)

biometric information acquisition means for acquiring biometric information of a user;
a numerical value generation means for generating a numerical value based on the biometric information;
start instruction means for instructing the stimulation means for stimulating the user to start stimulation when the numerical value exceeds a first threshold;
stop instruction acquisition means for acquiring a stop instruction of the stimulation from the user to the stimulation means;
setting means for setting the first threshold value based on the numerical value when the stop instruction is acquired;
stop instructing means for instructing the stimulation means to stop stimulation when the numerical value exceeds a second threshold;
A stimulus control device comprising:

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