JP7330012B2 - Wiper control parameter matching device, wiper control parameter matching method, and wiper control parameter matching program - Google Patents

Description

The present invention relates to a wiper control parameter matching device, a wiper control parameter matching method, and a wiper control parameter matching program for performing a control parameter matching test for controlling a wiper.

A controlled wiper is known in which a wiper controller feedback-controls a motor. The wiper control device has a map that defines the target values of the angular velocity and angle of the drive shaft of the motor that drives the wiper, and drives the motor according to this map. Various control parameters may be used to create a map depending on the specifications of the motor, etc. In this case, the evaluation values regarding the wiping performance of the wiper, or the wiper operating sound, reverse sound, etc. are appropriate for the control parameter. tuned to be

JP 2014-37189 A

Currently, tuning of control parameters is performed while relying on the intuition and experience of operators. For this reason, it is difficult to obtain the optimum solution for the control parameters, and there is a problem that it takes time and effort.

SUMMARY OF THE INVENTION An object of the present invention is to provide a wiper control parameter matching apparatus and the like that can obtain a control parameter matching solution without requiring complicated work.

In one aspect
a parameter selection unit that selects values of control parameters to be input to a motor control unit that drives a wiper motor of the wiper device;
a simulator for simulating a calculated value of a first state parameter of the wiper device driven by the wiper motor when the value of the control parameter selected by the parameter selection unit is input to the motor control unit;
The selected by the parameter selection unit based on a first difference between the calculated value of the first state parameter simulated by the simulator and the first target value related to the first state parameter a first suitability determination unit that determines suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection unit and determined to be compatible by the first compatibility determination unit is input to the motor control unit, the second wiper device is driven by the wiper motor. a second suitability determination unit that further determines suitability of the value of the control parameter selected by the parameter selection unit based on the measured value of the state parameter;
An apparatus for adapting wiper control parameters is provided, comprising:

According to the present invention, a suitable solution of control parameters can be obtained without complicated work.

FIG. 2 is a block diagram showing the configuration of a wiper control parameter matching device and the configuration of a wiper device to be subjected to an actual measurement test according to the present embodiment; It is a figure which illustrates the target speed map in the outward trip which a wiper arm rotates in one direction. FIG. 10 is a diagram illustrating a target speed map in a return trip in which the wiper arm rotates in another direction; It is a figure which illustrates the measured value (2nd state parameter) and target value (2nd target value) in the angular velocity of the drive shaft of a wiper arm. It is a figure which shows the relationship between the 2nd difference as a time series signal, and time. 4 is a flowchart showing an example of processing in the test control device; 9 is a flowchart showing another example of processing in the test control device;

Each embodiment will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a block diagram showing the configuration of the wiper control parameter matching device of the present embodiment and the configuration of the wiper device to be subjected to the actual measurement test.

As shown in FIG. 1, the wiper control parameter matching device 1 of this embodiment includes a test control device 10 that executes processing necessary for a test to obtain a control parameter matching solution, an angular velocity calculator 31, and an angle calculator. a detection device 30 comprising a portion 32 .

As shown in FIG. 1, a wiper device 40 to be tested includes a motor control unit 41 that executes control using control parameters, a wiper motor 42 that is driven based on the control in the motor control unit 41, and a wiper motor A link mechanism 43 connected to the drive shaft 42 and a wiper arm 44 rotationally driven in conjunction with the movement of the link mechanism 43 are provided. The wiper device 40 is configured in the same manner as an actual device mounted on a vehicle, and includes, for example, a windshield (not shown) of the vehicle so as to create an environment similar to that of the actual device.

The value of the control parameter is set in the motor control section 41, and the motor control section 41 feedback-controls the rotation speed of the wiper motor 42 according to the set control parameter value.

The control parameters set in the motor control unit 41 include target value parameters that define the target speed map of the wiper motor 42 and control gains used for feedback control by the motor control unit 41 .

2A and 2B are diagrams showing target speed maps of the wiper motor 42. FIG. FIG. 2A shows a target speed map for the forward pass in which the wiper arm 44 rotates in one direction (eg, clockwise direction), and FIG. Velocity maps are shown respectively.

As shown in FIGS. 2A and 2B, the target speed map defines the angular speed of the wiper motor 42 in association with the angle of the wiper motor 42 . 2A and 2B, the target value (first target value) of the angular velocity is indicated by a solid line 51. FIG. FIGS. 2A and 2B show an example in which the wiper arm 44 starts at a low speed from the initial position, gradually accelerates to reach the maximum speed in the outward trip, then decelerates, and then shifts to the return trip. On the return trip, the wiper arm 44 rotates in a direction opposite to that of the forward trip, but similarly to the outward trip, the wiper arm 44 is accelerated, decelerated, and returned to the initial position in sequence from a low speed state. The wiper motor 42 repeats a reciprocating motion combining an outward trip and a return trip.

The shape of the curve of the target speed map of the wiper motor 42 is defined by a combination of multiple parameters. That is, a combination of a plurality of control parameters is normally used as target speed parameters that define the target speed map. In the wiper control parameter adaptation device 1, a plurality of sets of setpoint parameter values can be tested.

Also, normally, the wiping cycle of the wiper arm 44 needs to be switched in a plurality of stages between a short cycle and a long cycle depending on the amount of rainfall and the like. Therefore, for each wiping cycle of the wiper arm 44, a target speed map for the wiper motor 42 is prepared that matches the cycle of the reciprocating motion corresponding to that cycle. Therefore, it is necessary to prepare a different combination of target value parameters for each period of reciprocating motion of the wiper motor 42 .

The target velocity map may define upper and lower angular velocity values indicated by dotted lines 52 and 53 in FIGS. 2A and 2B. The upper limit value and lower limit value of the angular velocity can be, for example, a value that indicates a constant ratio or a value that indicates a constant difference with respect to the first target value. This upper limit value and lower limit value are used for determination by the first conformity determination unit 15, which will be described later.

As described above, some of the control parameters can be control gains used for feedback control by the motor control section 41 . The control gain includes a proportional gain, an integral gain, or a differential gain driving axis that defines the feedback amount when the wiper motor 42 is driven by the motor control section 41 . Any portion of the proportional, integral and derivative gains may be included in the control parameters, or all of the proportional, integral and derivative gains may be included in the control parameters. As with the target value parameter, different control gains can be selected depending on the wiping cycle of the wiper arm 44 . It is also possible to select a fixed control gain regardless of the wiping period of the wiper arm 44 .

As shown in FIG. 1, the environment of the wiper system 40 is controlled by an environment controller 50 . The environmental control device 50 controls environmental factors necessary for the test, such as the amount of rainfall to the windshield, the amount of wind to the windshield, and the direction of the wind, in addition to the environmental temperature. The environment control device 50 can control the environment of the wiper device 40 while conducting the actual measurement test. As a result, control parameters (target value parameters and control gains) that are compatible with various environments can be extracted through the test by the wiper control parameter matching device 1 .

Next, the configuration of the test control device 10 will be described.

As shown in FIG. 1, the test control apparatus 10 includes a parameter reception unit 11, a parameter selection unit 12, a simulator 13, a first difference derivation unit 14, a first conformity determination unit 15, and a measured value acquisition unit 16. , a second difference derivation unit 17 , a second compatibility determination unit 18 , a target map storage unit 21 , a measured target value storage unit 22 , and a compatibility parameter storage unit 23 .

The parameter accepting unit 11 accepts setting of a range of values of control parameters to be tested. As described above, the control parameters include target value parameters and control gains.

The operator of the test control device 10 can set the range of values of the control parameters to be set in the motor control section 41 via the parameter reception section 11 to perform the actual measurement test. Any method may be used to set the value range of the control parameter. Specifically, for example, the operator can specify the range of values for each of the plurality of control parameters. If there are constraints on the relationships between control parameters, they can also be specified.

The operator can set any one of the target value parameter and the control gain as the control parameter via the parameter reception unit 11, or set the value range of both. Any one of the target value parameter and the control gain can also be specified as a fixed value.

The parameter selection unit 12 selects a set of control parameter values from the range of control parameter values set via the parameter reception unit 11 .

The parameter selection unit 12 also selects a new set of control parameter values in the genetic algorithm. The genetic algorithm treats candidate solutions (a set of control parameter values in this embodiment) as genes, and preferentially selects those with good results in the actual measurement test described later, and performs crossover (recombination), etc. This is a method of searching for the optimum solution by repeating the operation.

Specifically, as the current generation, N individuals (groups of control parameter values) are randomly generated in advance, and narrowed down by simulation calculation by the simulator 13, which will be described later. Furthermore, an actual measurement test, which will be described later, is performed on the individuals narrowed down by the simulation calculation. Then, individuals with good results in the actual measurement test are preferentially used to generate N individuals of the next generation.

By repeating the above operations a plurality of times, an optimum solution (a set of control parameter values) can be obtained. Since the genetic algorithm itself is a well-known method, detailed description thereof will be omitted.

The simulator 13 performs simulation calculation using a set of control parameter values selected by the parameter selection unit 12 . Specifically, the simulator 13 calculates the first state parameters of the wiper device 40 by driving the wiper motor 42 when the set of control parameter values selected by the parameter selection unit 12 is input to the motor control unit 41. A value is simulated. A first state parameter is, for example, the angular velocity of the drive shaft of the wiper motor 42 .

A first difference derivation unit 14 derives a first difference based on the calculation result of the simulator 13 and the target speed map. The first difference is, for example, the calculation result of the angular velocity of the wiper motor 42 by the simulator 13 (an example of the first state parameter) and the angular velocity of the wiper motor 42 defined by the target velocity map (an example of the first target value). Difference. The angular velocity of the wiper motor 42 is defined in association with the angle of the wiper motor 42 . That is, the target speed map defines the target angular speed of the wiper motor 42 in association with the angle of the wiper motor 42 at that time. In this case, the first difference is the difference between the angular velocity (first state parameter) calculated by the simulator 13 and the angular velocity (first target value) of the wiper motor 42 defined by the target velocity map. It is derived in correspondence with the angle. Also, the angle of the wiper motor 42 can be defined in association with time. In this case, for example, the target speed map can define the angle of the wiper motor 42 in association with the elapsed time from the start of wiping. Alternatively, the target speed map may define the angular speed of the wiper motor 42 in association with the elapsed time from the start of wiping. In this case, as the first difference, the difference between the angle (first state parameter) calculated by the simulator 13 and the angle (first target value) of the wiper motor 42 defined by the target speed map is used at the start of wiping. It is derived in association with the elapsed time from .

The first suitability determination unit 15 determines the suitability of the set of control parameter values selected by the parameter selection unit 12 based on the first difference derived by the first difference derivation unit 14 . The first suitability determination unit 15 determines, for example, the difference (first difference) is within a predetermined range.

For example, in FIGS. 2A and 2B, the dotted line 52 is the upper limit of the angular velocity, and the dotted line 53 is the lower limit of the angular velocity. At this time, if the angular velocity calculated by the simulator 13 is between the upper limit value and the lower limit value sandwiching the target value indicated by the solid line 51, the first suitability determination unit 15 affirms the suitability of the set of control parameter values. . That is, when the wiper motor 42 is within the predetermined angle range, the first difference is the difference between the first target value and the upper limit value (an example of the specified value) indicated by the solid line 51 and the first target value and the lower limit value (an example of the specified value), the first suitability determination unit 15 affirms the suitability of the set of control parameter values. Further, when this condition is not satisfied, that is, when there is an angle of the wiper motor 42 such that the angular velocity calculated by the simulator 13 does not fall between the upper limit value and the lower limit value, the first suitability determination unit 15 controls Deny the suitability of a set of parameter values.

Note that, as described above, the upper limit and lower limit of the angular velocity can be defined in the target velocity map. Also, the upper limit value and the lower limit value of the angular velocity can be set to a value that indicates a constant ratio or a value that indicates a constant difference with respect to the first target value.

In this embodiment, as a result of the simulated calculation by the simulator 13, only the control parameter value sets in which the angular velocity of the wiper motor 42 is between the upper limit value and the lower limit value are transferred to the step of the actual measurement test. Therefore, it is possible to effectively narrow down the set of control parameter values to be subjected to the actual measurement test, and to efficiently find a set of suitable control parameter values.

The measured value acquisition unit 16 performs a measured value test using a set of control parameter values whose compatibility is recognized by the first compatibility determination unit 15, and acquires measured values. The actual measurement value acquisition unit 16 sets a set of control parameter values whose compatibility is recognized by the first compatibility determination unit 15 in the motor control unit 41 . In addition, the measured value acquisition unit 16 instructs the motor control unit 41 to perform a measured test, that is, to rotate the wiper motor 42, and the measured value obtained by associating the calculation result by the angular velocity calculation unit 31 of the detection device 30 with the time. to get as

An instruction from the measured value acquisition unit 16 may be given to the environment control device 50 , and the environment of the wiper device 40 may be controlled based on the instruction from the measured value acquisition unit 16 .

The second difference deriving unit 17 derives a second difference based on the measured value (an example of the second state parameter) and the target value (an example of the second target value) acquired by the measured value acquiring unit 16. . The second difference is, for example, the difference between the measured value (second state parameter) of the angular velocity of the drive shaft of the wiper arm 44 calculated by the angular velocity calculator 31 and the target value (second target value) of the angular velocity. is.

FIG. 3A is a diagram illustrating an actual measurement value (second state parameter) and a target value (second target value) of the angular velocity of the drive shaft of the wiper arm 44. FIG. As shown in FIG. 3A , the target value (second target value) of the angular velocity of the drive shaft of the wiper arm 44 is defined in association with the angle of the drive shaft of the wiper arm 44 .

As shown in FIG. 3A, in both the outward trip and the return trip, the measured angular velocity (second state parameter) has a difference from the angular velocity target value (second target value), that is, the second difference. The second difference is derived by the second difference deriving section 17 as a value associated with the angle of the drive shaft of the wiper arm 44 .

FIG. 3B is a diagram showing the relationship between the second difference as a time-series signal and time. As described above, the measured value acquisition unit 16 acquires the calculation result of the angular velocity calculation unit 31 of the detection device 30 as the measured value associated with the time. Therefore, as shown in FIG. 3B, the second difference derivation unit 17 can derive the second difference as a time-series signal associated with time.

The second conformity determining unit 18 selects a parameter selecting unit based on the second difference derived by the second difference deriving unit 17, which is associated with the angle of the drive shaft of the wiper arm 44 shown in FIG. 3A. 12 determines the suitability of the set of control parameter values selected.

Specifically, the second suitability determination unit 18 evaluates the ability of the angular velocity of the wiper motor 42 simulated by the simulator 13 to follow the second target value. Based on this followability, the suitability of the set of control parameter values selected by the parameter selection unit 12 is determined.

As the followability evaluation index, for example, the root sum of squares (RSS) shown in the formula (1) can be used. Note that the formula (1) exemplifies a case where there are 64 points i as actual measurement points for one cycle of the movement of the wiper arm 44 . The term σi−mi corresponds to the second difference.

When the square root of the sum of squares shown in formula (1) is used as the followability evaluation index, the second suitability determination unit 18 compares the value of the square root of the sum of squares shown in formula (1) with a predetermined threshold value. Based on this, the suitability of the set of control parameter values selected by the parameter selection unit 12 can be determined. For example, when the value of the square root of the sum of squares shown in equation (1) is equal to or less than the threshold, the suitability of the set of control parameter values selected by the parameter selection unit 12 is affirmed. Further, when the value of the square root of the sum of squares shown in the formula (1) exceeds the threshold value, the suitability of the set of control parameter values selected by the parameter selection unit 12 is denied.

In determining the suitability of the set of control parameter values selected by the parameter selection unit 12, the second suitability determination unit 18 can use an evaluation index different from the followability evaluation index.

For example, the second matching determination unit 18 calculates the total harmonic distortion (THD) and noise (N ;noise) By using the effective value of the component as an evaluation index, the suitability of the set of control parameter values selected by the parameter selection unit 12 can be determined. Total harmonic distortion is a value representing the degree of signal distortion, and is represented by the ratio between the sum of harmonic components and the fundamental component. The sum of the total harmonic distortion and the effective value of noise (THD+N) can also be used as an evaluation index . Let V1 be the rms value of the sine wave signal, V2, V3, . is given by equations (2) and (3).

In equation (2), _V1 is the effective value of the component (fundamental wave component) of the reciprocating cycle (wiping cycle) of the wiper arm 44 in the second difference. The second difference includes a component (fundamental wave component) of the reciprocating cycle (wiping cycle) of the wiper arm 44, and the effective value of this component greatly affects the value of the square root of the sum of squares shown in equation (1). On the other hand, the high-frequency component contained in the reciprocating motion of the wiper arm 44 has a greater effect on the wiping stability of the wiper or the feeling of the motion of the wiper. For example, even if the value of the square root of the sum of squares shown in formula (1) as the followability evaluation index is below the threshold, the reciprocating motion of the wiper arm 44 contains large high-frequency components, i.e., angular velocity pulsation. When is large, the wiping stability of the wiper is lowered, or the human feeling for the movement of the wiper is deteriorated. Thus, the effective value of the high-order frequency component has a relatively large effect on the wiping stability or feel of the wiper. Therefore, a value using total harmonic distortion is suitable as an index of wiper wiping stability or feeling.

Therefore, in this embodiment, the sum of the effective values of harmonic distortion and noise (THD+N) is used as an evaluation index for the wiping stability of the wiper. The second suitability determination unit 18 affirms the suitability of the set of control parameter values selected by the parameter selection unit 12 when the sum of the effective values of harmonic distortion and noise (THD+N) is equal to or less than a predetermined threshold. do. Further, the second suitability determination unit 18 denies suitability of the set of control parameter values selected by the parameter selection unit 12 when the sum of the effective values of harmonic distortion and noise (THD+N) exceeds this threshold. do.

Instead of the total harmonic distortion, a harmonic component of any order may be used as an index of the wiping stability of the wiper independently of the high frequency components of other orders. For example, if the rms values of higher-order harmonic components are considered important as indices, weighting can be performed so that the rms values of higher-order harmonic components are weighted more. For example, only harmonic components of third or higher order may be extracted. Alternatively, different weighting may be applied to each harmonic between odd and even orders. Also, the effective value of noise may be evaluated separately from the harmonic components. Further, the suitability of a set of control parameter values may be determined using only the harmonic content.

It should be noted that the set of control parameter values must be selected so that the evaluation values relating to the wiping performance of the wiper, or the wiper operating noise, reversal noise, etc., are optimized. For this reason, in general, in the actual measurement test, elements other than the judgment in the second conformity judgment section 18 are also added, and finally the optimal set of control parameter values is extracted.

Target map storage unit 21 stores the range of values of target value parameters that define the target speed map (first target value) of wiper motor 42 shown in FIGS. 2A and 2B. The value range of the target value parameter corresponds to the value range of the target value parameter set via the parameter reception unit 11 .

The measured target value storage unit 22 stores a target value (second target value) in the measured test. As described above, this target value (second target value) is, for example, the target value of the angular velocity of the drive shaft of the wiper arm 44 . Since the second target value is a value to be associated with the first target, it may be updated in the test control device 10 according to the first target value stored in the target map storage unit 21. .

The compatible parameter storage unit 23 stores a set of control parameter values selected by the parameter selection unit 12 and whose compatibility is affirmed by the second compatibility determination unit 18 .

As shown in FIG. 1 , the detection device 30 includes an angular velocity calculator 31 and an angle calculator 32 . The angular velocity detector 31 calculates the angular velocity of the drive shaft of the wiper arm 44 , and the angle detector 32 calculates the angle of the drive shaft of the wiper arm 44 . As shown in FIG. 1 , the state (angular velocity, angle, etc.) of the drive shaft of the wiper arm 44 is acquired by the encoder 45 and given to the detection device 30 as a signal from the encoder 45 . Angular velocity detector 31 and angle detector 32 respectively calculate the angular velocity and angle of the drive shaft of wiper arm 44 based on the signal from encoder 45 .

2A and 2B show an example in which the first target value and the first state parameter are the angular velocity of the drive shaft of the wiper motor 42, the first target value and the first state parameter are the driving force of the wiper motor 42. It may be the angle of the axis. In this case, for example, the angle of the drive shaft of the wiper motor 42 is defined as a value associated with time, and the first difference is also defined as a value associated with time.

3A shows an example in which the second target value and the second state parameter are the angular velocity of the drive shaft of the wiper arm 44, the second target value and the second state parameter are the drive shaft of the wiper arm 44. may be the angle of In this case, for example, the angle of the drive shaft of the wiper arm 44 is defined as a value associated with time.

Next, an example of processing in the test control device 10 will be described. FIG. 4 is a flowchart showing an example of processing in the test control device 10. As shown in FIG.

In step S102 of FIG. 4, the parameter reception unit 11 receives an operator's operation to set the value range of the control parameter. Here, the operator can set the value range of the control parameter to be tested via the parameter reception unit 11 . Further, the parameter receiving unit 11 determines the data of the target map storage unit 21, that is, the target value parameter that defines the target speed map (first target value) of the wiper motor 42 based on the received value range of the target value parameter. Update the range of values.

As described above, the control parameters include a target value parameter that defines a target speed map, which will be described later, and a proportional gain, integral gain, differential gain, or the like that defines the feedback amount when the wiper motor 42 is driven by the motor control unit 41. Includes control gains. At step S102, the operator can arbitrarily set the range of the target value parameter and the control gain.

In step S103, the parameter selection unit 12 randomly sets N pairs of target value parameter values within the range of target value parameter values set in step S102. The set N sets of target value parameter values correspond to N individuals in the above genetic algorithm.

In step S104, the parameter selection unit 12 selects one value set from the N sets of target value parameter values set in step S103. Here, one of the N individuals (the set of control parameter values) in the above genetic algorithm is selected.

In step S106, the simulator 13 calculates the first state parameter values of the wiper device 40 driven by the wiper motor 42 when the set of control parameter values selected in step S104 is input to the motor control unit 41 as follows: Simulate calculations. Here, the simulator 13 calculates a first state parameter of the wiper device 40 under certain circumstances. As the constant environment, conditions such as a constant amount of rain in no wind and a constant wiping cycle of the wiper device 40 can be set. These conditions are met by a predetermined selection of the value of the target value parameter and a predetermined control in climate controller 50 .

By using the simulator 13 to simulate only the state of the wiper device 40 under a certain environment, the burden of calculation by the simulator 13 can be reduced. However, if the burden of calculation by the simulator 13 is not a problem, simulation calculations may be performed in various environments. By performing simulated calculations in various environments, it is possible to more accurately extract a set of control parameter values at the stage of simulated calculations.

As mentioned above, the first state parameter calculated by simulator 13 is, for example, the angular velocity of the drive shaft of wiper motor 42 . By subjecting only such parameters to simulation calculation, the load of calculation by the simulator 13 can be reduced. Further, by simulating the angular velocity of the drive shaft of the wiper motor 42, which is a basic state parameter for determining the driving state of the wiper device 40, the driving state of the wiper device 40 can be efficiently grasped.

However, other state parameters may be calculated in addition to or instead of the angular velocity of the drive shaft of the wiper motor 42 if the computational burden of the simulator 13 is not a problem. For example, the angular velocity of the drive shaft of wiper arm 44 may be calculated. As shown in FIG. 1, the rotation of the drive shaft of wiper motor 42 is normally transmitted to the drive shaft of wiper arm 44 via link mechanism 43 . Therefore, the amount of rotation of the drive shaft of the wiper motor 42 and the amount of rotation of the drive shaft of the wiper arm 44 do not have a one-to-one correspondence. However, if a simulation including the behavior of the link mechanism 43 is possible, the motion of the wiper arm 44 can be grasped more directly by calculating the angular velocity of the drive shaft of the wiper arm 44 .

In step S108, the first difference deriving unit 14 calculates the difference (first difference) between the calculated value of the first state parameter simulated by the simulator 13 and the first target value related to the first state parameter. to derive As described above, the first target value is defined by the target speed map stored in target map storage section 21 (FIG. 1). Also, as described above, the first state parameter is the angular velocity of the drive shaft of the wiper motor 42 obtained by simulated calculation. Similar to the angular velocity indicated by the target speed map, the angular velocity of the drive shaft of the wiper motor 42 is simulated as a value associated with the angle of the drive shaft of the wiper motor 42 .

As described above, the first difference calculated by the first difference derivation unit 14 is the angular velocity of the drive shaft of the wiper motor 42 defined in the target speed map and the angular velocity of the drive shaft of the wiper motor 42 obtained by simulation calculation. is the difference between This difference is derived as an angular velocity difference associated with the angle of the drive shaft of the wiper motor 42 .

In step S110, the first compatibility determination unit 15 determines the compatibility of the set of control parameter values selected by the parameter selection unit 12 based on the first difference derived by the first difference derivation unit 14 in step S108. , that is, whether or not the first matching condition is satisfied. Here, the first suitability determination unit 15 uses, for example, the upper limit value and the lower limit value of the angular velocity of the drive shaft of the wiper motor 42 defined in the target speed map to determine the suitability of the set of control parameter values.

That is, in step S110, when the first difference falls between the upper limit value and the lower limit value indicated by the dotted lines 52 and 53 in FIGS. 3A and 3B, the parameter selection unit 12 confirms the suitability of the set of control parameter values selected. In this case, the process proceeds to step S112.

Further, when there is a region (the angle of the drive shaft of the wiper motor 42) where the first difference does not fit between the upper limit value and the lower limit value indicated by the dotted line 52 and the dotted line 53, the first suitability determination unit 15 selects the parameter selection unit 12 negates the suitability of the set of control parameter values selected by . In this case, the process returns to step S104.

In step S112, the first compatibility determination unit 15 acquires, from the measured value acquisition unit 16, a set of control parameter values for which compatibility is affirmed by the first compatibility determination unit 15 in step S110.

In step S<b>114 , the measured value acquisition unit 16 starts acquiring measured values (second state parameters) from the angular velocity calculation unit 31 and the angle detection unit 32 of the detection device 30 .

In step S<b>116 , the measured value acquisition unit 16 inputs the set of control parameter values acquired from the first conformity determination unit 15 in step S<b>112 and the target speed map acquired from the target map storage unit 21 to the motor control unit 41 . In addition, the measured value acquisition unit 16 instructs the motor control unit 41 to execute the driving operation using the set of control parameter values input in step S112. As a result, the wiper motor 42 is started to rotate by the motor control unit 41 .

In step S118, the measured value acquiring unit 16 repeats determination as to whether or not the actual measurement has been completed. If the determination is affirmative, the measured value acquisition unit 16 terminates acquisition of measured values (second state parameters) from the angular velocity calculation unit 31 and the angle detection unit 32 of the detection device 30, and starts the driving operation. The motor controller 41 is instructed to stop. As a result, the rotation of the wiper motor 42 by the motor control unit 41 is stopped. After that, the process proceeds to step S120.

In step S120, the second difference derivation unit 17 obtains the angular velocity (second state parameter) from the angular velocity calculation unit 31 and the angle from the angle detection unit 32 acquired by the measured value acquisition unit 16, and the target map storage unit 21 A second difference is derived based on the angular velocity (second target value) indicated by the target velocity map (FIGS. 3A and 3B) stored in .

In step S<b>122 , the second matching determination unit 18 calculates the square root sum of squares shown in the above equation (1) based on the second difference derived by the second difference derivation unit 17 .

In step S124, the second suitability determination unit 18 determines whether or not the value of the square root sum of squares calculated in step S122 is equal to or less than a predetermined threshold value, that is, whether or not the second suitability condition is satisfied. If this determination is affirmative, the second suitability determination unit 18 determines that the set of control parameter values selected by the parameter selection unit 12 is compatible with respect to the value of the square root of the sum of squares, that is, the followability, and The process proceeds to step S126. If this determination is denied, the second compatibility determining unit 18 determines that the set of control parameter values selected by the parameter selecting unit 12 is not compatible with respect to the value of the square root of the sum of squares, that is, the followability, and The process returns to step S104.

In step S126, the second matching determination unit 18 calculates the effective harmonic distortion and noise shown in the above equations (2) and (3) based on the second difference derived by the second difference deriving unit 17. Calculate the sum of the values (THD+N). The sum (THD+N) of the calculated effective value of harmonic distortion and noise is stored in the second suitability determination section 18 together with the set of control parameter values selected by the parameter selection section 12 .

In step S128, the actual measurement value acquiring unit 16 determines whether or not N actual measurement tests have already been performed. If the determination is affirmative, the process proceeds to step S130. Return to S104. Here, it is determined whether or not actual measurement tests have been performed for the N individuals (groups of control parameter values) in the above genetic algorithm.

In addition, in step S128, the determination is not affirmative unless the actual measurement test has already been executed N times. Therefore, selection of a new set of control parameter values is repeated N times or more in step S104 until the determination in step S128 is affirmative, and the process proceeds to the simulation step (step S106).

In step S130, the second suitability determination unit 18 compares the sum of the effective values of individual harmonic distortion and noise (THD+N) calculated and held in step S126 with a predetermined threshold. Then, the second suitability determination unit 18 determines whether or not there is a sum (THD+N) of the effective values of harmonic distortion and noise whose value is equal to or less than a predetermined threshold value, i.e., whether or not the second suitability condition is satisfied. to decide. If this determination is affirmative, the second suitability determination unit 18 determines that there is a set that is compatible with respect to the sum of the effective values of harmonic distortion and noise (THD+N), that is, wiping stability, and the process proceeds to step Proceed to S132. If this judgment is denied, the second suitability judging section 18 judges that there is no suitability for the sum of the effective values of harmonic distortion and noise (THD+N), that is, the wiping stability, and the process proceeds to step Proceed to S134.

In step S132, the second suitability determination unit 18 adapts the set of control parameter values determined to be suitable in step S130 with respect to the sum of the effective values of harmonic distortion and noise (THD+N), that is, the wiping stability. The parameters are stored in the parameter storage unit 23, and the process ends.

In step S134, the parameter selection unit 12 sets N pairs of new control parameter values using a genetic algorithm. After that, the process returns to step S104. In step S134, the parameter selection unit 12 sets N sets of next-generation genes, that is, sets of new control parameter values, based on the results of the actual measurement test. That is, by an operation that preferentially leaves the gene of the set of control parameter values excellent in followability based on the square root of the sum of squares and wiping stability based on the sum of the effective values of harmonic distortion and noise (THD+N) to the next generation. , a new set of control parameter values is set.

In the above embodiment, as a result of the simulated calculation by the simulator 13, only when the first difference is equal to or less than the predetermined specified value (when the determination in step S110 is affirmative), the actual measurement test (processing after step S112) Transition. Therefore, through the simulation calculation by the simulator 13, it is possible to effectively extract a set of control parameter values that are highly likely to be compatible at the stage of the simulation calculation. Further, when the result of the simulation calculation by the simulator 13 is that the first difference is not equal to or less than the predetermined specified value, the process does not proceed to the actual measurement test (the process after step S112). Therefore, it is possible to prevent a set of control parameter values that are highly likely to be denied suitability in the end from performing an actual measurement test. Therefore, it is possible to efficiently obtain a suitable solution of the control parameters without repeating the actual measurement test excessively.

In the above-described embodiment, in the actual measurement test, in addition to the followability of the wiper motor 42, the suitability of the set of control parameter values is determined with respect to the wiping stability based on the movement of the wiper arm 44. For this reason, it is possible to search and extract a set of control parameter values that are excellent in wiping stability and that match human feelings. In general, selecting a set of control parameter values that optimizes the followability of the wiper motor 42 does not always result in excellent wiping stability. However, according to the present embodiment, it is possible to achieve compatibility between the followability of the wiper motor 42, wiping stability and feeling.

FIG. 5 is a flowchart showing another example of processing in the test control device 10. As shown in FIG. In FIG. 5, the same step numbers are assigned to substantially the same processes as those shown in FIG.

In step S102 of FIG. 5, the parameter reception unit 11 receives an operator's operation for setting the value range of the control parameter. Further, the parameter receiving unit 11 determines the data of the target map storage unit 21, that is, the target value parameter that defines the target speed map (first target value) of the wiper motor 42 based on the received value range of the target value parameter. Update the range of values.

In step S103, the parameter selection unit 12 randomly sets N pairs of target value parameter values within the range of target value parameter values set in step S102. The set N sets of target value parameter values correspond to N individuals in the above genetic algorithm.

In step S104, the parameter selection unit 12 selects one value set from the N sets of target value parameter values set in step S103. Here, one of the N individuals (the set of control parameter values) in the above genetic algorithm is selected.

In step S106, the simulator 13 calculates the first state parameter values of the wiper device 40 driven by the wiper motor 42 when the set of control parameter values selected in step S104 is input to the motor control unit 41 as follows: Simulate calculations.

In step S108, the first difference deriving unit 14 calculates the difference (first difference) between the calculated value of the first state parameter simulated by the simulator 13 and the first target value related to the first state parameter. to derive

In step S110, the first compatibility determination unit 15 determines the compatibility of the set of control parameter values selected by the parameter selection unit 12 based on the first difference derived by the first difference derivation unit 14 in step S108. , that is, whether or not the first matching condition is satisfied. Here, the first suitability determination unit 15 uses, for example, the upper limit value and the lower limit value of the angular velocity of the drive shaft of the wiper motor 42 defined in the target speed map to determine the suitability of the set of control parameter values.

If the suitability of the set of control parameter values selected by the parameter selection unit 12 is affirmed, the process proceeds to step S112. If the suitability of the set of control parameter values selected by the parameter selection unit 12 is denied, the process returns to step S104.

In step S112, the first compatibility determination unit 15 acquires, from the measured value acquisition unit 16, a set of control parameter values for which compatibility is affirmed by the first compatibility determination unit 15 in step S110.

In step S<b>114 , the measured value acquisition unit 16 starts acquiring measured values (second state parameters) from the angular velocity calculation unit 31 and the angle detection unit 32 of the detection device 30 .

In step S<b>116 , the measured value acquisition unit 16 inputs the set of control parameter values acquired from the first conformity determination unit 15 in step S<b>112 and the target speed map acquired from the target map storage unit 21 to the motor control unit 41 . In addition, the measured value acquisition unit 16 instructs the motor control unit 41 to execute the driving operation using the set of control parameter values input in step S112. As a result, the wiper motor 42 is started to rotate by the motor control unit 41 .

In step S118, the measured value acquiring unit 16 repeats determination as to whether or not the actual measurement has been completed. If the determination is affirmative, the measured value acquisition unit 16 terminates acquisition of measured values (second state parameters) from the angular velocity calculation unit 31 and the angle detection unit 32 of the detection device 30, and starts the driving operation. The motor controller 41 is instructed to stop. As a result, the rotation of the wiper motor 42 by the motor control unit 41 is stopped. After that, the process proceeds to step S120.

In step S120, the second difference derivation unit 17 obtains the angular velocity (second state parameter) from the angular velocity calculation unit 31 and the angle from the angle detection unit 32 acquired by the measured value acquisition unit 16, and the target map storage unit 21 A second difference is derived based on the angular velocity (second target value) indicated by the target velocity map (FIGS. 3A and 3B) stored in .

In step S<b>122 , the second matching determination unit 18 calculates the square root sum of squares shown in the above equation (1) based on the second difference derived by the second difference deriving unit 17 . The calculated square root of sum of squares is held in the second conformance determination section 18 together with the set of control parameter values selected by the parameter selection section 12 .

In step S126, the second matching determination unit 18 calculates the effective harmonic distortion and noise shown in the above equations (2) and (3) based on the second difference derived by the second difference deriving unit 17. Calculate the sum of the values (THD+N). The sum (THD+N) of the calculated effective value of harmonic distortion and noise is stored in the second suitability determination section 18 together with the set of control parameter values selected by the parameter selection section 12 .

In step S128, the actual measurement value acquiring unit 16 determines whether or not N actual measurement tests have already been performed. If the determination is affirmative, the process proceeds to step S230. Return to S104. Here, it is determined whether or not actual measurement tests have been performed for the N individuals (groups of control parameter values) in the above genetic algorithm.

In step S230, the second suitability determination unit 18 performs the calculation based on the square root of the sum of squares calculated and held in step S122 and the sum of the effective values of harmonic distortion and noise (THD+N) calculated and held in step S126. , whether or not there is a matching individual (a set of control parameter values), that is, whether or not the second matching condition is satisfied.

The second compatibility condition can be set arbitrarily, but there are individuals (groups of control parameter values) that are recognized to be compatible with both the square root of the sum of squares and the sum of the rms values of harmonic distortion and noise (THD+N). In this case, the second matching condition should be satisfied. For example, thresholds are provided for each of the square root of the sum of squares and the sum of the effective values of harmonic distortion and noise (THD+N). can be set as a compatibility condition. Alternatively, the square root of the sum of squares and the sum of the effective values of harmonic distortion and noise (THD+N) may be scored, and whether or not the second matching condition is satisfied may be determined based on the sum of both scores. .

If this determination is affirmative, the second suitability determining unit 18 determines both the followability of the wiper motor 42 corresponding to the square root of the sum of squares and the wiping stability corresponding to the sum of the effective values of harmonic distortion and noise (THD+N). , it is determined that there is a matching pair, and the process proceeds to step S132. If this determination is denied, the second matching determination unit 18 determines that there is no matching pair, and the process proceeds to step S134.

In step S132, the second compatibility determination unit 18 stores the set of control parameter values determined to be compatible in step S230 in the compatibility parameter storage unit 23, and terminates the process.

In step S134, the parameter selection unit 12 sets N pairs of new control parameter values using a genetic algorithm. After that, the process returns to step S104. In step S134, the parameter selection unit 12 sets N sets of next-generation genes, that is, sets of new control parameter values, based on the results of the actual measurement test. That is, by an operation that preferentially leaves the gene of the set of control parameter values excellent in followability based on the square root of the sum of squares and wiping stability based on the sum of the effective values of harmonic distortion and noise (THD+N) to the next generation. , a new set of control parameter values is set.

In the processing shown in FIG. 5, a condition related to both the square root of the sum of squares and the sum of the effective values of harmonic distortion and noise (THD+N) is used as the second matching condition. Therefore, by applying a genetic algorithm, it is possible to efficiently derive a solution (a set of control parameter values) that has an excellent balance between followability and wiping stability.

In addition, the following additional remarks will be disclosed with respect to the above examples.

[Appendix 1]
a parameter selection unit (12) for selecting values of control parameters to be input to a motor control unit (41) for driving a wiper motor (42) of a wiper device (40);
A simulator (13) for simulating a calculated value of a first state parameter of the wiper device driven by the wiper motor when the value of the control parameter selected by the parameter selection unit is input to the motor control unit. and,
The selected by the parameter selection unit based on a first difference between the calculated value of the first state parameter simulated by the simulator and the first target value related to the first state parameter a first suitability determination unit (15) that determines suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection unit and determined to be compatible by the first compatibility determination unit is input to the motor control unit, the second wiper device is driven by the wiper motor. a second suitability determination unit (18) that further determines suitability of the value of the control parameter selected by the parameter selection unit based on the measured values of the state parameters of
an adaptation device for wiper control parameters, comprising:

According to the configuration of Supplementary Note 1, when the first compatibility determination unit determines that there is compatibility, the second compatibility determination unit further determines the compatibility of the value of the control parameter. It is possible to efficiently search and extract values of control parameters having compatibility while suppressing the number of times of determining compatibility. Also, if the properties of the first state parameter and the second state parameter are different, it is possible to determine the suitability of the value of the control parameter from many aspects. Therefore, it is possible to search and extract control parameter values that are compatible with a plurality of elements.

[Appendix 2]
Apparatus for adapting wiper control parameters according to claim 1, wherein the first state parameter is an angular velocity corresponding to an angle of the drive shaft of the wiper motor or an angle corresponding to time.

According to the configuration of Supplementary Note 2, the simulation calculation is performed using the angular velocity or angle of the drive shaft of the wiper motor, which is a basic state parameter for determining the driving state of the wiper device, as the first state parameter. The state can be grasped efficiently.

[Appendix 3]
The first compatibility determining unit, based on the comparison between the first difference and a specified value, according to supplementary note 1 or supplementary note 2, determines the compatibility of the value of the control parameter selected by the parameter selection unit Wiper control parameter adaptation device.

According to the configuration of Supplementary Note 3, the suitability of the value of the control parameter is determined based on the comparison between the first difference and the specified value, so the followability of the first state parameter to the first target value Good control parameter values can be searched and extracted efficiently.

[Appendix 4]
Apparatus for adapting wiper control parameters according to any one of appendices 1 to 3, wherein the second state parameter is an angular velocity corresponding to an angle of the drive shaft of the wiper arm or an angle corresponding to time.

According to the configuration of Supplementary Note 4, since the angular velocity or angle of the drive shaft of the wiper arm, which is directly related to the wiping motion of the wiper device, is actually measured, the compatibility of the value of the control parameter is directly related to the actual operation of the wiper device. can be determined in

[Appendix 5]
The second suitability determination unit, based on a second difference between the measured value of the second state parameter acquired by the measured value acquisition unit and a second target value related to the second state parameter, The wiper control parameter matching device according to any one of appendices 1 to 4, wherein suitability of the value of the control parameter selected by the parameter selection unit is determined.

According to the configuration of Supplementary Note 5, it is possible to make a determination according to the amount of deviation of the measured value of the second state parameter from the second target value, so it is possible to efficiently determine the suitability of the value of the control parameter. can.

[Appendix 6]
The wiper control parameter value according to Supplementary Note 5, wherein the second suitability determination unit determines suitability of the control parameter value selected by the parameter selection unit based on the square root of the sum of squares of the second difference. Compliant equipment.

According to the configuration of Supplementary Note 6, the value of the control parameter is adapted based on the square root of the sum of squares of the second difference, which is a representative value indicating the amount of deviation of the measured value of the second state parameter from the second target value. Therefore, it is possible to efficiently search and extract the value of the control parameter that makes the measured value of the second state parameter well follow the second target value.

[Appendix 7]
The second matching determination unit adapts the value of the control parameter selected by the parameter selection unit based on the sum of the total harmonic distortion of the second difference as the time-series signal and the effective value of noise. 6. A wiper control parameter adaptation device according to claim 5, wherein the wiper control parameter adaptation device determines

According to the configuration of Supplementary Note 7, the sum of the total harmonic distortion of the second difference and the effective value of the noise reflects the magnitude of the high-frequency component and pulsation included in the second difference. Further, the high-frequency component and the magnitude of pulsation included in the second difference have a relatively large effect on the wiping stability or feel of the wiper. Therefore, it is possible to efficiently search and extract control parameter values that are suitable from the viewpoint of wiper wiping stability or feeling.

[Appendix 8]
The wiper control parameter adapting device according to any one of appendices 1 to 7, wherein the parameter selection unit selects a new value of the control parameter based on the determination result of the second suitability determination unit.

According to the configuration of Supplementary Note 8, a new control parameter value is selected based on the determination result of the second compatibility determination unit. Therefore, a compatible control parameter value is selected as the new control parameter value. more likely to be Therefore, it is possible to efficiently search and extract the value of the control parameter having compatibility.

[Appendix 9]
9. The wiper control parameter adapting apparatus according to claim 8, wherein the parameter selection unit selects a new value of the control parameter using a genetic algorithm.

According to the configuration of Supplementary Note 9, since a new control parameter value is selected using a genetic algorithm, a control parameter value with a high probability of compatibility is efficiently selected as the new control parameter value. be done. Therefore, it is possible to efficiently search and extract the value of the control parameter having compatibility.

[Appendix 10]
The wiper control parameter matching device according to any one of appendices 1 to 9, wherein the control parameter is a target value parameter that defines the first target value.

According to the configuration of Supplementary Note 10, since the suitability of the target value parameter is determined by the first suitability determination unit and the second suitability determination unit, it is possible to efficiently search and extract the suitability of the first target value. can.

[Appendix 11]
The wiper control parameter matching device according to any one of appendices 1 to 9, wherein the control parameter is a control gain used in control in the motor control unit.

According to the configuration of Supplementary Note 11, since the suitability of the control gain is determined by the first suitability determining section and the second suitability determining section, it is possible to efficiently search and extract the suitability of the target value of the control gain. .

[Appendix 12]
a parameter selection step of selecting values of control parameters to be input to a motor control unit that drives a wiper motor of the wiper device;
a simulation step of simulating a calculated value of a first state parameter of the wiper device driven by the wiper motor when the control parameter value selected in the parameter selection step is input to the motor control unit;
selected by the parameter selection step based on a first difference between the calculated value of the first state parameter simulated by the simulation step and a first target value related to the first state parameter a first suitability determination step for determining suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection step and determined to be compatible by the first compatibility determination step is input to the motor control unit, the wiper device is operated by driving the wiper motor. a second suitability determination step for further determining the suitability of the control parameter values selected by the parameter selection step based on the measured values of the state parameters of
A method of adapting wiper control parameters, comprising:

According to the configuration of Supplementary Note 12, when the first compatibility determination unit determines that there is compatibility, the second compatibility determination unit further determines the compatibility of the value of the control parameter. It is possible to efficiently search and extract values of control parameters having compatibility while suppressing the number of times of determining compatibility. Also, if the properties of the first state parameter and the second state parameter are different, it is possible to determine the suitability of the value of the control parameter from many aspects. Therefore, it is possible to search and extract control parameter values that are compatible with a plurality of elements.

[Appendix 13]
a parameter selection step of selecting values of control parameters to be input to a motor control unit that drives a wiper motor of the wiper device;
a simulation step of simulating a calculated value of a first state parameter of the wiper device driven by the wiper motor when the control parameter value selected in the parameter selection step is input to the motor control unit;
selected by the parameter selection step based on a first difference between the calculated value of the first state parameter simulated by the simulation step and a first target value related to the first state parameter a first suitability determination step for determining suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection step and determined to be compatible by the first compatibility determination step is input to the motor control unit, the wiper device is operated by driving the wiper motor. a second suitability determination step for further determining the suitability of the control parameter values selected by the parameter selection step based on the measured values of the state parameters of
A wiper control parameter adaptation program that causes a computer to execute

According to the configuration of Supplementary Note 13, when the first compatibility determination unit determines that there is compatibility, the second compatibility determination unit further determines the compatibility of the value of the control parameter. It is possible to efficiently search and extract values of control parameters having compatibility while suppressing the number of times of determining compatibility. Also, if the properties of the first state parameter and the second state parameter are different, it is possible to determine the suitability of the value of the control parameter from many aspects. Therefore, it is possible to search and extract control parameter values that are compatible with a plurality of elements.

Although each embodiment has been described in detail above, it is not limited to a specific embodiment, and various modifications and changes are possible within the scope of the claims. It is also possible to combine all or more of the constituent elements of the above-described embodiments.

1 Wiper Control Parameter Adaptation Device 12 Parameter Selection Section 13 Simulator 15 First Adaptation Determination Section 18 Second Adaptation Determination Section 40 Wiper Device 41 Motor Control Section 42 Wiper Motor 44 Wiper Arm

Claims (10)

a motor control unit that executes control using control parameters; a wiper motor that is driven based on the control in the motor control unit; a link mechanism that is connected to the drive shaft of the wiper motor; a wiper arm that is rotationally driven by a wiper device;
A first state parameter that is an angular velocity corresponding to the angle of the drive shaft of the wiper motor or an angle corresponding to time when the value of the control parameter selected by the parameter selection unit is input to the motor control unit a simulator for simulated calculation of calculated values;
The selected by the parameter selection unit based on a first difference between the calculated value of the first state parameter simulated by the simulator and the first target value related to the first state parameter a first suitability determination unit that determines suitability of the value of the control parameter;
The drive shaft of the wiper arm driven by the wiper motor when the value of the control parameter selected by the parameter selection unit and determined to be compatible by the first compatibility determination unit is input to the motor control unit. A second suitability judgment that further judges the suitability of the value of the control parameter selected by the parameter selector based on the measured value of the second state parameter , which is the angular velocity corresponding to the angle or the angle corresponding to time. Department and
an adaptation device for wiper control parameters, comprising: 2. The method according to claim 1 , wherein the first compatibility determination unit determines compatibility of the value of the control parameter selected by the parameter selection unit based on a comparison between the first difference and a specified value. Fitting device for wiper control parameters. The second suitability determination unit selects the 3. Device for adapting wiper control parameters according to claim 1 or 2 , for determining the suitability of values of control parameters. 4. The second suitability determination unit determines suitability of the value of the control parameter selected by the parameter selection unit based on the square root of the sum of squares of the second difference as a time-series signal. Apparatus for adapting wiper control parameters as described. The second suitability determination unit determines the suitability of the value of the control parameter selected by the parameter selection unit based on the sum of the total harmonic distortion of the second difference as a time-series signal and the effective value of noise. 4. The device for adapting wiper control parameters of claim 3 , wherein the device determines: 6. The parameter selection unit according to any one of claims 1 to 5 , wherein the parameter selection unit selects a new value of the control parameter using a genetic algorithm based on the determination result of the second compatibility determination unit. Fitting device for wiper control parameters. The wiper control parameter adaptation device according to any one of claims 1 to 6 , wherein said control parameter is a target value parameter defining said first target value. The wiper control parameter matching device according to any one of claims 1 to 6 , wherein the control parameter is a control gain used in control in the motor control section. a motor control unit that executes control using control parameters; a wiper motor that is driven based on the control in the motor control unit; a link mechanism that is connected to the drive shaft of the wiper motor; a wiper arm that is rotationally driven by a wiper device , a parameter selection step of selecting a value of the control parameter to be input to the motor control unit;
A first state parameter that is an angular velocity corresponding to the angle of the drive shaft of the wiper motor or an angle corresponding to time when the control parameter value selected in the parameter selection step is input to the motor control unit. a simulation step of simulated calculation of the calculated value;
selected by the parameter selection step based on a first difference between the calculated value of the first state parameter simulated by the simulation step and a first target value related to the first state parameter a first suitability determination step for determining suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection step and determined to be compatible by the first compatibility determination step is input to the motor control unit, the drive shaft of the wiper arm driven by the wiper motor A second suitability determination that further determines the suitability of the value of the control parameter selected by the parameter selection step based on the measured value of a second state parameter that is the angular velocity corresponding to the angle or the angle corresponding to time. a step;
A method of adapting wiper control parameters, comprising: a motor control unit that executes control using control parameters; a wiper motor that is driven based on the control in the motor control unit; a link mechanism that is connected to the drive shaft of the wiper motor; a wiper arm that is rotationally driven by a wiper device , a parameter selection step of selecting a value of the control parameter to be input to the motor control unit;
A first state parameter that is an angular velocity corresponding to the angle of the drive shaft of the wiper motor or an angle corresponding to time when the control parameter value selected in the parameter selection step is input to the motor control unit. a simulation step of simulated calculation of the calculated value;
selected by the parameter selection step based on a first difference between the calculated value of the first state parameter simulated by the simulation step and a first target value related to the first state parameter a first suitability determination step for determining suitability of the value of the control parameter;
When the value of the control parameter selected by the parameter selection step and determined to be compatible by the first compatibility determination step is input to the motor control unit, the drive shaft of the wiper arm driven by the wiper motor A second suitability determination that further determines the suitability of the value of the control parameter selected by the parameter selection step based on the measured value of a second state parameter that is the angular velocity corresponding to the angle or the angle corresponding to time. a step;
A wiper control parameter adaptation program that causes a computer to execute

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