JP6326193B2 - Actuator drive system using shape memory alloy, electronic device, pulse width determination method and tactile feedback adjustment method - Google Patents

Description

  The present invention relates to a driving technique for an actuator using a shape memory alloy, and further relates to a technique for adjusting vibration intensity.

  When the actuator for tactile feedback that gives the user a sense of operation (haptic feedback) is built into the touch screen of a tablet terminal, a flat keyboard without key traveling, or a touch-type operation switch without key stroke There is. Until now, electromagnets, piezoelectric elements, vibration motors, etc. have been used for actuator drive parts. Recently, shape memory alloys (SMA) have advantages such as vibration strength, responsiveness, and size. Has come to adopt.

  Patent Document 1 discloses an impact generating actuator that changes energy applied to a shape memory alloy according to an ambient temperature. In the same document, when the duty ratio of a single pulse signal is set based on the normal temperature, and the ambient temperature is lower than the normal temperature, there is a risk of causing an increase in the SMA expansion / contraction time and a decrease in the amount of contraction due to insufficient heating. When the ambient temperature is higher than room temperature, it is described that there is a possibility that the SMA expansion / contraction time is shortened or excessive heating is caused.

Japanese Unexamined Patent Publication No. 2016-15698

  An actuator using SMA can adjust the vibration intensity by adjusting the crest value and pulse width of a single pulse voltage to be applied. In order to change the peak value, it is necessary to change the output voltage of the DC / DC converter, which complicates the circuit configuration. Even if a single pulse voltage with the same peak value and pulse width is applied to the same type of actuator, individual acceleration, operating environment temperature, drive voltage, and installation conditions are different, so the same acceleration can be obtained. I can't. Furthermore, in an actuator incorporated in an electronic device, it is difficult to obtain a pulse width corresponding to a predetermined vibration intensity because the test is restricted.

  Accordingly, an object of the present invention is to provide a drive system capable of adjusting the vibration intensity of an actuator using a shape memory alloy. A further object of the present invention is to provide a drive system capable of adjusting the vibration intensity while being incorporated in an electronic device. A further object of the present invention is to provide a drive system that reduces power consumption. It is a further object of the present invention to provide an electronic device to which such a drive system is applied, a pulse width determination method, and a tactile feedback adjustment method.

  An actuator drive system using a shape memory alloy according to the present invention obtains a maximum vibration intensity based on a switch that applies a pulse voltage to the actuator, a change in resistance when a voltage is applied to the shape memory alloy, and an elapsed time. A pulse width adjusting unit that acquires a reference pulse width for controlling the switch, and a pulse signal generating unit that controls the operation of the switch with a pulse voltage having the reference pulse width.

  An electronic device according to the present invention includes a vibrator that provides tactile feedback, an actuator using a shape memory alloy, a switch that applies a pulse voltage to the actuator, and a change in resistance when a voltage is applied to the shape memory alloy. A pulse width adjustment unit that acquires a reference pulse width for obtaining a maximum vibration intensity based on the elapsed time; and a pulse signal generation unit that controls the operation of the switch with a pulse voltage of the reference pulse width.

  A method for determining a pulse width of a pulse voltage applied to an actuator using a shape memory alloy according to the present invention applies a voltage to the shape memory alloy, detects a change in resistance during energization of the shape memory alloy, The pulse width is determined based on the change and energization time. The method of adjusting the strength of tactile feedback by the impact drive actuator using the shape memory alloy according to the present invention includes conducting a test energization to the impact drive actuator, measuring the resistance of the shape memory alloy during the test energization, and An indication of the vibration intensity of the tactile feedback is received, and a single pulse voltage having a pulse width corresponding to the indicated vibration intensity is generated from the reference pulse width acquired based on the change in resistance and the energization time.

  According to the present invention, a drive system capable of adjusting the vibration intensity of an actuator using a shape memory alloy can be provided. Further, according to the present invention, a drive system capable of adjusting the vibration intensity in a state of being incorporated in an electronic device can be provided. Furthermore, according to the present invention, a drive system for reducing power consumption can be provided. Furthermore, according to the present invention, it is possible to provide an electronic device to which such a drive system is applied, a pulse width determination method, and a tactile feedback adjustment method.

It is a schematic diagram for demonstrating the structure of an impact drive type actuator. It is a figure for demonstrating a mode that the temperature and length of SMA101 change with a thermal cycle. It is a figure for demonstrating the relationship between the temperature T and resistance R of SMA101 at the time of expansion-contraction by a complete thermal cycle. It is a figure for demonstrating the relationship between the elapsed time t, the acceleration G, and resistance R when the DC voltage 61 of the voltage V1 is applied to the impact drive type actuator at the time t0. 2 is a schematic functional block diagram of an actuator drive system 200. FIG. 4 is a flowchart showing an operation procedure of the actuator drive system 200.

[the term]
Special terms used in this specification will be explained. An actuator using SMA operates in a hysteresis cycle (thermal cycle) between a martensite phase (low temperature phase) and an austenite phase. The actuator itself moves regularly to give vibration to the vibrating body. The actuator using the SMA includes an impact drive type actuator and a vibration type actuator.

  The impact driven actuator can generate the desired vibration with one single pulse voltage or one thermal cycle. The vibration type actuator generates a target vibration with a plurality of single pulse voltages repeatedly applied at predetermined intervals that enable thermal cycling. Although the drive system according to the present invention can be applied to any type of actuator, in this specification, an impact drive type actuator will be described as an example.

  The single pulse voltage is a voltage that exists only for a short predetermined energization time, and applies heat necessary for driving the actuator to the SMA. The single pulse voltage can be rephrased as a single pulse current because it acts as a current on the contraction of the SMA. The voltage waveform and the current waveform during the energization time can be arbitrary waveforms such as a rectangular wave, a differential wave, a triangular wave, or a staircase wave whose peak value changes stepwise.

  The vibrating body corresponds to an object that vibrates as necessary with one single pulse voltage applied to the impact driving actuator. The vibrating body is not particularly limited, but may be an object that gives tactile feedback to a finger touched when a human performs an operation, such as a touch panel, a keyboard, or a switch. When a single pulse voltage is continuously applied to the impact drive type actuator and the vibration type actuator, it is necessary to provide a predetermined interval in order to maintain a complete thermal cycle.

  FIG. 1 is a schematic diagram for explaining the structure of the impact drive actuator 100. The impact drive actuator 100 includes a stator 103, a mover 105, an SMA 101, and a bias material 107. The impact drive type actuator 100 gives impact or transient vibration to the vibrating body 10. The SMA 101 repeatedly operates with a unidirectional shape memory and a bias force. However, the present invention can also be applied to an SMA that stores a bidirectional shape.

  The facing surfaces where the stator 103 and the movable element 105 face each other are formed in a wave shape so that the concaves and convexes of each other can be fitted. Between the opposing surfaces of the stator 103 and the mover 105, a linear SMA 101 is disposed. For example, a nickel / titanium alloy, a titanium / nickel / copper alloy, or the like can be selected as the SMA 101, but there is no particular limitation. The bias member 107 can be formed of an elastic body that applies a bias force in a direction in which the stator 103 and the movable element 105 approach each other.

  FIG. 1A shows a state in which the SMA 101 exhibits a flexible property at a temperature equal to or lower than the martensite transformation end temperature Mf (FIG. 2). The biasing member 107 is biased by the biasing force applied to the movable element 105 so that the movable element 105 approaches the stator 103 and the opposed surfaces are fitted. The SMA 101 plastically deformed on the facing surface extends to the maximum length along the shape of the facing surfaces of the stator 103 and the mover 105. A state in which the SMA 101 is plastically deformed by the shape of the opposing surface and the bias material 107 and has a maximum length is referred to as a fully extended state.

  FIG. 1B shows a state in which the SMA 101 contracts and hardens as the temperature rises and returns to the memorized shape exceeding the austenite transformation end temperature Af (FIG. 2). A state in which the contraction of the SMA 101 is referred to as a completely contracted state. During the transition from the fully extended state to the fully contracted state, the mover 105 is displaced so as to increase the distance from the stator 103 against the bias force. When a single pulse voltage having reference pulse widths Wsm and Wxm (FIG. 4) is applied to the impact drive actuator 100, the SMA 101 undergoes a phase transition from a fully expanded state to a fully contracted state in one thermal cycle, and the energization time is further increased. When stopped, it returns to the fully extended state.

  FIG. 2 is a diagram for explaining how the temperature and length of the SMA 101 change due to thermal cycling. The horizontal axis indicates the temperature T of the SMA 101, and the vertical axis indicates the length L. When the temperature is equal to or lower than the martensitic transformation end temperature Mf, the whole of the SMA 101 is almost phase-transformed into the martensitic phase. In the martensite phase, since SMA 101 has flexibility, it undergoes plastic deformation under a bias force.

  When a voltage is applied to the SMA 101 phase-transformed into the martensite phase and energized and heated, the martensite reverse transformation starts and shrinkage starts when the temperature exceeds the austenite transformation start temperature As. Then, when the temperature reaches the austenite transformation end temperature Af, the contraction is completed and a complete contraction state having a length of L1 (L1 <L0) is obtained. A process in which the temperature rises from the austenite transformation start temperature As to the austenite transformation end temperature Af is referred to as a complete temperature rise process.

  When energization is stopped in the fully contracted state, the temperature is lowered due to heat dissipation, and martensitic transformation starts at the martensitic transformation start temperature Ms and gradually softens. During this time, the SMA 101 gradually expands due to the degree of softening and the bias force. Then, when the temperature reaches the martensite transformation end temperature Mf, the extension is finished and a full extension state having a length of L0 is obtained. A process in which the temperature falls from the martensite transformation start temperature Ms to the martensite transformation end temperature Mf is referred to as a complete temperature drop process.

  The length of the SMA 101 expands and contracts by L0−L1 = d during a complete thermal cycle formed by one complete temperature increase process and one complete temperature decrease process. The mover 105 applies bending stress to the vibrating body 10 in a completely contracted state with a length L1, and releases it in a fully extended state with a length L0. The vibrating body 10 vibrates in response to sudden application and release of stress by a single pulse voltage. The magnitude of vibration can be adjusted by the displacement amount and the displacement speed of the mover 105.

  The displacement amount of the mover 105 depends on the contraction amount of the SMA 101, that is, the temperature. For example, even when a single pulse voltage with the same peak value is used, the SMA 101 contracts only to the length L2 (L2> L1) when the energization time ends at the temperature T1 before reaching the austenite transformation end temperature Af because the pulse width is short. The displacement of the mover 105 is smaller than that in the complete temperature raising process.

  Accordingly, the displacement of the vibrating body 10 is reduced and the acceleration is reduced. A temperature rising process with a single pulse voltage that ends the energization time before reaching the austenite transformation end temperature Af is referred to as an incomplete temperature rising process. Since the voltage that continues after the complete temperature raising process is finished does not affect the displacement of the mover 105, it is consumed as wasted energy. If the application time is too long, the deterioration of the SMA 101 is promoted.

  FIG. 3 is a diagram for explaining the relationship between the temperature T and the resistance R of the SMA 101 when expanding and contracting in a complete thermal cycle. FIG. 3 shows a resistance curve 57 in the complete temperature increase process and a resistance curve 59 in the complete temperature decrease process. When a DC voltage V is applied to the SMA 101, the temperature rises due to Joule heat. The resistance of the SMA 101 at the time of temperature rise can be calculated from the voltage V and the current I flowing through the SMA 101 by R = V / I. In the complete temperature rising process, the resistance increases as the temperature rises, and the resistance R reaches the maximum value 53 in the vicinity of the austenite transformation end temperature Af.

  As the current continues to flow, the resistance R becomes a substantially constant value after the inflection point 51. The inflection point 51 can be specified as a point at which the sign of the second derivative of the function R = f (T) of the resistance R and the temperature T changes or reaches a predetermined value. Since the SMA 101 does not displace the mover 105 when the phase transfer to the austenite phase is completed, the acceleration of the vibrating body does not increase. If the energization time of the single pulse voltage is made longer than necessary to raise the temperature, the deterioration of the SMA 101 is promoted and power is consumed wastefully.

  In the experiment, it has been confirmed that the acceleration of the impact drive type actuator 100 becomes substantially constant after the SMA 101 exceeds the inflection point 51. Therefore, if the inflection point 51 can be known, the power consumption can be reduced by setting the minimum energization time necessary for obtaining the maximum acceleration. The minimum energization time of a single pulse voltage necessary for obtaining the maximum acceleration is referred to as a reference pulse width.

  FIG. 4 is a diagram for explaining the relationship between the elapsed time t, the acceleration G of the vibrating body 10, and the resistance R when the test voltage 61 of the DC voltage V1 is applied to the impact driving actuator 100 at time t0. The elapsed time t corresponds to the pulse width of a single pulse voltage when energization is stopped at times t1 to t5. Time t1 corresponds to a sufficiently long energization time (test pulse width Wp) set to acquire the reference pulse width.

  The resistance of the SMA 101 to which the test voltage 61 is applied rises along the resistance curves 57s and 57x in the complete temperature rising process. Here, the resistance curve 57 s and the acceleration curve 63 s correspond to data relating to a reference impact drive actuator, and the resistance curve 57 x and the acceleration curve 63 x are impact drive types that are adjustment targets for adjustment to an appropriate pulse width. This corresponds to data related to the actuator 100.

  The vibration strength of the impact drive actuator 100 can be specified by a vibration strength such as a displacement amount, a displacement speed, or a displacement acceleration of the vibrating body. In the present embodiment, the acceleration suitable for evaluating the strength of tactile feedback will be described as an example, but other characteristics may be used. The acceleration curve 63x indicates the acceleration G corresponding to a single pulse voltage having a pulse width determined at the elapsed time t. In the experiment, it has been confirmed that the maximum acceleration Gxm is reached at the elapsed time t3 when the resistance reaches the inflection point 51x, and thereafter the acceleration G does not increase even if the pulse width W is widened. In a state where the maximum acceleration Gxm is reached, it is considered that the martensite reverse transformation is completed and the length of the SMA is contracted to L1.

  The reference pulse width Wxm corresponds to the minimum pulse width that determines the elapsed time t3 required to obtain the maximum acceleration Gxm. When a single pulse voltage having a reference pulse width Wxm is applied, it is possible to maximize the power efficiency of the impact driving actuator 100 that operates so as to apply the maximum acceleration Gxm. However, since the maximum acceleration Gxm of the impact drive type actuator 100 changes due to individual differences or use conditions, the reference pulse width Wxm changes individually. The reference pulse width Wxm includes an elapsed time t3 until the resistance reaches the inflection point 51x, an elapsed time t from when the maximum value 53x is reached to the inflection point 51x (t6 <t <t3), Or it is good also as elapsed time t (t3 <t) until it arrives at the state which can be considered that resistance does not change after exceeding the inflection point 51x.

  The adjusted acceleration nGxm in a range smaller than the maximum acceleration Gxm can be obtained through the incomplete temperature rising process. A pulse width for obtaining the adjustment acceleration nGxm is referred to as an adjustment pulse width Wxa. Here, n is a vibration intensity n (n <1), which is a constant indicating a relative acceleration with respect to the maximum acceleration Gxm. The user can assume the desired vibration intensity n by recognizing the maximum acceleration Gxm given to the vibrating body 10 by the impact driving actuator 100 perceived when a single pulse voltage having the test pulse width Wp is applied. .

  Up to now, in order to obtain an acceleration with a desired vibration intensity n, the maximum acceleration Gxm is obtained with a single pulse voltage having a sufficiently long pulse width exceeding the reference pulse width Wxm, and at a predetermined ratio to a sufficiently long pulse width. The adjustment pulse width was set. However, since the pulse width set for obtaining the maximum acceleration Gxm is longer than the reference pulse width Wxm and cannot be specified to exceed the reference pulse width Wxm, the adjustment pulse width is determined by the tactile feedback intended by the user. It did not reflect strength.

  The maximum acceleration Gxm of the impact drive type actuator 100 can be assumed to fall within a certain range at the time of manufacture as a basic characteristic of the product, but the acceleration curve 63x is unknown. Although it is difficult to acquire the data of the acceleration curve 63x of all the impact drive type actuators 100 before shipping, the maximum acceleration Gsm indicated by the acceleration curve 63s and the reference pulse corresponding thereto for the reference impact drive type actuators. It is possible to obtain the adjustment pulse width Wsa corresponding to the adjustment acceleration Gsm corresponding to the width Wsm and the vibration intensity n.

  However, even if the data of the acceleration curve 63s obtained in advance is applied to the impact drive actuator 100 having the acceleration curve 63x, accuracy is lacking due to individual differences and the like. In the present embodiment, the test pulse 61 is applied to obtain the reference pulse width Wxm of the impact drive actuator 100, and the impact drive to be adjusted is obtained from data corresponding to the acceleration curve 63s of the reference impact drive actuator. The adjustment pulse width Wxa of the mold actuator 100 is calculated.

  FIG. 5 is a schematic functional block diagram of the actuator drive system 200. The actuator driving system 200 can be mounted on all electronic devices that require tactile feedback such as a keyboard, a touch screen, and a switch. However, the use of the actuator drive system 200 according to the present invention is not limited to the application of tactile feedback, and is applied to an electronic device that needs to obtain an accurate reference pulse width and adjustment pulse width under restricted conditions. Can do. The actuator driving system 200 can be applied not only to an impact driving type actuator but also to a vibration type actuator.

  In one example, the actuator drive system 200 includes a pulse width adjustment unit 201, a reference table 203, a pulse signal generation unit 205, a DC voltage source 207, a voltage / current detector 209, an impact drive actuator 100, a keyboard 213, an N-type FET 215, and power. The capacitor 211 that constitutes the source is used. The DC voltage source 207 is composed of a DC / DC converter and outputs a predetermined DC voltage.

  The capacitor 211 is charged during the OFF period of the FET 215, discharged during the ON period, and energizes the impact drive actuator 100. The voltage / current detector 209 detects the voltage and current of a single pulse voltage applied to the SMA 100. The keyboard 213 corresponds to an example of the vibrating body 10 in FIG. The impact drive actuator 100 gives tactile feedback to the substrate of the keyboard 213 at the timing when the keyboard is operated.

  The FET 215 is an element that controls switching of a DC voltage, and a bipolar transistor may be adopted. Further, the capacitor 211 may not be provided if the DC voltage source 207 has a sufficient capacity. The pulse width adjustment unit 201, the reference table 203, and the pulse signal generation unit 205 can be configured by a SoC (System on Chip) or a dedicated controller.

  The pulse width adjustment unit 201 acquires the voltage and current to be applied to the SMA 101 from the voltage / current detector 209, and sets the adjustment pulse width Wxa calculated with reference to the reference table 203 in the pulse signal generation unit 205. The reference table 203 includes reference data corresponding to the acceleration curve 63s of the shock driving actuator that is a reference. The reference data is composed of a plurality of pairs of vibration intensity n and adjustment pulse width Wsa for each peak value of a single pulse voltage, and includes a reference pulse width Wsm corresponding to the maximum acceleration.

  The pulse width adjustment unit 201 includes a user interface for the user to adjust the vibration intensity n. The user can perceive tactile feedback at the maximum acceleration through the user interface and then recognize the desired vibration intensity n. The pulse signal generation unit 205 applies a single pulse signal having the adjustment pulse width Wxa or the reference pulse width Wxm set by the pulse width adjustment unit 201 to the gate of the FET 215 at the timing when the key event is received from the keyboard 213.

  FIG. 6 is a flowchart showing an operation procedure of the actuator drive system 200. Here, when there is an impact drive type actuator (reference actuator) with a known acceleration curve 63s, the impact drive type actuator 100 (target actuator) is the same type as the reference actuator and the acceleration curve 63x is unknown with respect to the vibration intensity n. A procedure for obtaining the reference pulse width Wxm and the adjustment pulse width Wxa will be described. It is assumed that the target actuator is mounted on an electronic device.

  In block 301, a predetermined test voltage is applied to the reference actuator at the factory to obtain reference data corresponding to the acceleration curve 63s. A single pulse voltage having various pulse widths is applied to the reference actuator, and a set of the pulse width Wsa and the acceleration nGsm constituting the acceleration curve 63 s is obtained from the maximum value 53 s and the inflection point 51 s. Store. The acceleration nGsm is acquired until the pulse width is gradually increased to reach the maximum acceleration Gsm of n = 1.

  The pulse width when the maximum acceleration Gsm is reached becomes the reference pulse width Wsm. In block 303, the user performs an operation for changing the vibration intensity n through the user interface provided by the pulse width adjustment unit 201 of the target actuator. Here, the pulse width adjustment unit 201 can apply a single pulse voltage of the test pulse width Wp several times to make the user perceive tactile feedback at the maximum acceleration Gxm. In block 305, the pulse width adjustment unit 201 applies a test voltage 61 (FIG. 4) having a preset test pulse width Wp to the pulse signal generation unit 205 at time t0.

  In block 307, the pulse width adjustment unit 201 measures the elapsed time from the time t0. In block 309, the pulse width adjusting unit 201 periodically calculates the resistance R from the voltage V and current I applied to the SMA 101. The resistance R can be obtained relatively easily even when the impact drive actuator 100 is incorporated in an electronic device. In block 311, the pulse width adjustment unit 201 calculates a second derivative with respect to the function R = f (t) indicating the resistance curve 57x, and obtains the time t3 when the inflection point 51x is reached. In block 313, the pulse width adjustment unit 201 acquires the reference pulse width Wxm from time t3.

  In block 315, the user inputs the vibration intensity n selected based on the maximum acceleration Gxm perceived through the user interface provided by the actuator drive system 200. The pulse width adjustment unit 201 can allow the user to select character information such as strong, medium, or weak describing the ratio with respect to the maximum acceleration Gxm or numerical information such as 10, 7, 5, 3 as the vibration intensity n. .

  Although the acceleration curves 63x and 63s have different maximum accelerations Gsm and Gxm and reference pulse widths Wsm and Wxm, it can be assumed that the shapes of the acceleration curves 63s and 63x are similar. That is, it can be assumed that the ratio of the reference pulse width Wsm and the adjustment pulse width Wsa to the vibration intensity n and the ratio of the reference pulse width Wxm and the adjustment pulse width Wxa are equal. In block 317, the pulse width adjustment unit 201 obtains an adjustment pulse width Wxa for obtaining the acceleration nGxm with respect to the vibration intensity n by the standard actuator from the reference table 203.

The pulse width adjustment unit 201 can calculate the adjustment pulse width Wxa of the target actuator using Equation (1).
Wxa = Wsa × (Wxm / Wsm) (1)
In the present embodiment, the adjustment pulse width Wxa can be calculated without using the reference table 203 by using the reference pulse width Wxm acquired by applying the test voltage 61. For example, the reference pulse width Wxm is made to correspond to the vibration intensity 1, the pulse width 0 is made to correspond to the vibration intensity n = 0, and the interval between them is approximated by a straight line or other approximate curve, and the vibration intensity n corresponding to the adjusted pulse width Wxa is obtained. Can be obtained. Here, it can be assumed that the maximum acceleration Gxm of each target actuator falls within a certain range at the time of manufacture as a basic characteristic of the product, and the vibration strength n can be assumed to be equal to the vibration strength n of the reference actuator within a certain range. In block 319, the pulse width adjustment unit 201 sets the adjustment pulse width Wxa in the pulse signal generation unit 205.

  The pulse width adjustment unit 201 can set the reference pulse width Wxm corresponding to the maximum acceleration Gxm when the adjustment pulse width Wxa is not set in the pulse signal generation unit 205. Since the reference pulse width Wxm is the pulse width with the highest power efficiency for obtaining the maximum acceleration Gxm, the actuator drive system 200 can accurately adjust the vibration intensity n and achieve the maximum vibration intensity with the minimum energy. Can be obtained. In addition, the actuator drive system 201 can easily obtain the adjustment pulse width Wxa for the predetermined vibration intensity n simply by applying the test voltage 61 in a state where the actuator drive system 201 is mounted on an electronic device.

  Although the present invention has been described with the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and is known so far as long as the effects of the present invention are achieved. It goes without saying that any configuration can be adopted.

10 Vibrators 51, 51s, 51x Inflection points 53, 53s, 53x Maximum values of resistance 57, 57s, 57x Resistance curve 61 Test voltage 63s, 63x Acceleration curve 100 Impact drive actuator 101 Shape memory alloy (SMA)
103 Stator 105 Movable element 107 Bias material 200 Actuator drive system Wxm, Wsm Reference pulse width Wxa, Wsa Adjustment pulse width

Claims (10)

An actuator drive system using a shape memory alloy,
A switch for applying a pulse voltage to the actuator;
A pulse width adjusting unit for obtaining a pulse width corresponding to the elapsed time to reach the vicinity of the inflection point resistance changes when a voltage is applied to the shape memory alloy is present after passing through a maximum value,
And a pulse signal generation unit configured to control the operation of the switch with a pulse voltage having the pulse width . An actuator drive system using a shape memory alloy,
A switch for applying a pulse voltage to the actuator;
A pulse width adjusting unit for obtaining a pulse width corresponding to the elapsed time to reach a state in which resistance changes when a voltage is applied to the shape memory alloy is considered to not change after passing through a maximum value,
And a pulse signal generation unit configured to control the operation of the switch with a pulse voltage having the pulse width . An actuator drive system using a shape memory alloy,
A switch for applying a pulse voltage to the actuator;
A pulse width adjustment unit that acquires a reference pulse width corresponding to a minimum pulse width at which the actuator generates a maximum vibration intensity based on a maximum value of a resistance that changes when a voltage is applied to the shape memory alloy;
A pulse signal generator for controlling the operation of the switch with a pulse voltage of the reference pulse width;
Reference data including a reference pulse width corresponding to a minimum pulse width at which a reference actuator of the same type as the actuator generates a maximum vibration intensity and an adjustment pulse width for generating a predetermined ratio of the vibration intensity to the maximum vibration intensity of the reference actuator A reference table for storing
The drive system in which the pulse width adjustment unit acquires an adjustment pulse width that generates the vibration intensity at the predetermined ratio with respect to the maximum vibration intensity of the actuator based on a reference pulse width of the actuator and the reference data . The drive system according to any one of claims 1 to 3, wherein the actuator is an impact drive type actuator. A vibrator that provides tactile feedback;
An actuator using a shape memory alloy;
A switch for applying a pulse voltage to the actuator;
A pulse width adjusting unit for obtaining a pulse width corresponding to the elapsed time to reach the vicinity of the inflection point resistance changes when a voltage is applied to the shape memory alloy is present after passing through a maximum value,
An electronic apparatus comprising: a pulse signal generation unit that controls the operation of the switch with a pulse voltage having the pulse width . A vibrator that provides tactile feedback;
An actuator using a shape memory alloy;
A switch for applying a pulse voltage to the actuator;
A pulse width adjusting unit for obtaining a pulse width corresponding to the elapsed time to reach a state in which resistance changes when a voltage is applied to the shape memory alloy is considered to not change after passing through a maximum value,
An electronic apparatus comprising: a pulse signal generation unit that controls the operation of the switch with a pulse voltage having the pulse width. A vibrator that provides tactile feedback;
An actuator using a shape memory alloy;
A switch for applying a pulse voltage to the actuator;
A pulse width adjustment unit that obtains a reference pulse width corresponding to a minimum pulse width that generates a maximum vibration intensity based on a maximum value of resistance that changes when a voltage is applied to the shape memory alloy;
A pulse signal generator for controlling the operation of the switch with a pulse voltage of the reference pulse width;
Reference data including a reference pulse width corresponding to a minimum pulse width at which a reference actuator of the same type as the actuator generates a maximum vibration intensity and an adjustment pulse width for generating a predetermined ratio of the vibration intensity to the maximum vibration intensity of the reference actuator And a reference table for storing
An electronic device in which the pulse width adjustment unit acquires an adjustment pulse width that generates the predetermined vibration intensity with respect to the maximum vibration intensity of the actuator based on a reference pulse width of the actuator and the reference data . A method for determining a pulse width of a pulse voltage applied to an actuator using a shape memory alloy,
Applying a voltage to the shape memory alloy;
Detecting a change in resistance during energization of the shape memory alloy;
Determining a pulse width corresponding to an elapsed time until the resistance reaches the vicinity of an inflection point existing after passing through the maximum value . A method for determining a pulse width of a pulse voltage applied to an actuator using a shape memory alloy,
Applying a voltage to the shape memory alloy;
Detecting a change in resistance during energization of the shape memory alloy;
Determining a pulse width corresponding to an elapsed time until reaching a state where the resistance can be regarded as not changing after passing through the maximum value . A method for determining a pulse width of a pulse voltage applied to an actuator using a shape memory alloy,
Applying a voltage to the shape memory alloy;
Detecting a change in resistance during energization of the shape memory alloy;
Determining a reference pulse width corresponding to a minimum pulse width at which the actuator generates a maximum vibration intensity based on a maximum value of the resistance that changes;
Reference data including a reference pulse width corresponding to a minimum pulse width at which a reference actuator of the same type as the actuator generates a maximum vibration intensity and an adjustment pulse width for generating a predetermined ratio of the vibration intensity to the maximum vibration intensity of the reference actuator Step to get the
Obtaining an adjustment pulse width that generates a vibration intensity of the predetermined ratio with respect to a maximum vibration intensity of the actuator based on a reference pulse width of the actuator and the reference data;
Having a method.

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