A storing section (70) stores a second initial contact instruction value, which is predefined as an instruction value for positioning a movable portion (5) to a second contact position where the movable portion (5) is contacted with a stopper (8), and an initial standby instruction value, which is p
A storing section (70) stores a second initial contact instruction value, which is predefined as an instruction value for positioning a movable portion (5) to a second contact position where the movable portion (5) is contacted with a stopper (8), and an initial standby instruction value, which is predefined as an instruction value for positioning the movable portion (5) to a specified standby position within a moving range of the movable portion (5). A correcting section (42) calculates an actual standby instruction value by correcting the initial standby instruction value, based on a second actual contact instruction value obtained when a contact detection section (41) has detected that the movable portion (5) is positioned to the second contact position, and the second initial contact instruction value. A setting section (43) sets a standby position corresponding to the actual standby instruction value, as an actual standby position of the movable portion (5).
대표청구항▼
1. A shape memory alloy driving device, comprising: a movable portion;a moving mechanism portion which includes a shape memory alloy member, and moves the movable portion;a restraining member which is contactable with the movable portion to thereby restrain a movement of the movable portion, and def
1. A shape memory alloy driving device, comprising: a movable portion;a moving mechanism portion which includes a shape memory alloy member, and moves the movable portion;a restraining member which is contactable with the movable portion to thereby restrain a movement of the movable portion, and defines a moving range of the movable portion;a drive control section which outputs a drive signal in accordance with an instruction value for positioning the movable portion to the shape memory alloy member, and controls the moving mechanism portion to move the movable portion by deforming the shape of the shape memory alloy member;a contact detecting section which detects whether the movable portion is positioned to a contact position in contact with the restraining member;a storing section which stores initial position information for determining a relation between a position of the movable portion and an instruction value in an initial state;a correcting section which calculates an actual standby instruction value, based on an actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the contact position, and the initial position information; anda setting section which sets a standby position corresponding to the actual standby instruction value, as an actual standby position of the movable portion. 2. The shape memory alloy driving device according to claim 1, wherein the initial position information includes an initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the contact position, and an initial standby instruction value which is predefined as an instruction value for positioning the movable portion to the standby position, andthe setting section calculates the actual standby instruction value, based on the actual contact instruction value, the initial contact instruction value, and the initial standby instruction value. 3. The shape memory alloy driving device according to claim 1, wherein the initial position information includes an initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the contact position, and a differential value between an initial standby instruction value which is predefined as an instruction value for positioning the movable portion to the standby position, and the initial contact instruction value, andthe setting section calculates the actual standby instruction value, based on the differential value and the actual contact instruction value. 4. The shape memory alloy driving device according to claim 2, wherein the correcting section calculates the actual standby instruction value, based on a displacement between the actual contact instruction value and the initial contact instruction value. 5. The shape memory alloy driving device according to claim 2, wherein the restraining member includes a first restraining member which restrains a movement of the movable portion over one of upper and lower limits of the moving range, and a second restraining member which restrains a movement of the movable portion over the other of the upper and lower limits of the moving range,the contact detecting section detects whether the movable portion is positioned to a first contact position where the movable portion is contacted with the first restraining member, and detects whether the movable portion is positioned to a second contact position where the movable portion is contacted with the second restraining member,the initial contact instruction value includes a first initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the first contact position, and a second initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the second contact position,the actual contact instruction value includes a first actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the first contact position, and a second actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the second contact position, andthe correcting section calculates the actual standby instruction value, based on the first initial contact instruction value, the second initial contact instruction value, the first actual contact instruction value, and the second actual contact instruction value. 6. The shape memory alloy driving device according to claim 1, wherein the contact detecting section detects a change in a resistance value of the shape memory alloy member to thereby detect the contact position. 7. The shape memory alloy driving device according to claim 1, wherein the contact detecting section detects a change in a current flowing through the shape memory alloy member or a voltage corresponding to the current to thereby detect the contact position. 8. The shape memory alloy driving device according to claim 1, wherein the contact detecting section is a contact sensor which is disposed at such a position as to detect a contact of the movable portion with the restraining member. 9. The shape memory alloy driving device according to claim 1, wherein the movable portion holds an image pickup lens for use in an image pickup device, andthe standby position is a reference focus position of the image pickup device. 10. The shape memory alloy driving device according to claim 1, wherein the movable portion holds an image pickup lens for use in an image pickup device, andthe standby position is a reference zoom position of the image pickup device. 11. The shape memory alloy driving device according to claim 1, wherein the correcting section calculates the actual standby instruction value when a power source of an image pickup device is turned on. 12. The shape memory alloy driving device according to claim 1, further comprising: a temperature detecting section which detects an ambient temperature, whereinthe correcting section calculates the actual standby instruction value, when the temperature detected by the temperature detecting section has changed by a predetermined value. 13. The shape memory alloy driving device according to claim 1, further comprising: a time measuring section which measures an operation time, whereinthe correcting section calculates the actual standby instruction value, when the operation time measured by the time measuring section has exceeded a predetermined time. 14. The shape memory alloy driving device according to, claim 1, further comprising: a number counting section which counts the number of times of operation, whereinthe correcting section calculates the actual standby instruction value, when the number of times of operation counted by the number counting section has changed by a predetermined value. 15. The shape memory alloy driving device according to claim 2, further comprising: a number counting section which counts the number of times of operation, whereinthe correcting section updates the initial contact instruction value and the initial standby instruction value with the actual contact instruction value and the actual standby instruction value respectively, when the number of times of operation counted by the number counting section has changed by a predetermined value. 16. A shape memory alloy driving device, comprising; a movable portion;a moving mechanism portion which includes a shape memory alloy member, and moves the movable portion;a restraining member which is contactable with the movable portion to thereby restrain a movement of the movable portion, and defines a moving range of the movable portion;a drive control section which outputs a drive current in accordance with an instruction value for positioning the movable portion to the shape memory alloy member, and controls the moving mechanism portion to move the movable portion by deforming the shape of the shape memory alloy member;a contact detecting section which detects whether the movable portion is positioned to a contact position in contact with the restraining member by detecting a change of the drive current;a storing section which stores initial position information for determining a relation between a position of the movable portion and an instruction value in an initial state;a correcting section which calculates an actual standby instruction value, based on an actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the contact position, and the initial position information; anda setting section which sets a standby position corresponding to the actual standby instruction value, as an actual standby position of the movable portion,wherein the drive control section adjusts the drive current to such a level that a resistance value of the shape memory alloy member becomes equal to a resistance value corresponding to the instruction value, andwherein the contact detecting section detects the contact position by detecting an inflection point of the drive current which appears as the instruction value is gradually increased. 17. The shape memory alloy driving device according to claim 16, wherein the initial position information includes an initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the contact position, and an initial standby instruction value which is predefined as an instruction value for positioning the movable portion to the standby position, andthe setting section calculates the actual standby instruction value, based on the actual contact instruction value, the initial contact instruction value, and the initial standby instruction value. 18. The shape memory alloy driving device according to claim 17, wherein the initial position information includes an initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the contact position, and a differential value between an initial standby instruction value which is predefined as an instruction value for positioning the movable portion to the standby position, and the initial contact instruction value, andthe setting section calculates the actual standby instruction value, based on the differential value and the actual contact instruction value. 19. The shape memory alloy driving device according to claim 18, wherein the correcting section calculates the actual standby instruction value, based on a displacement between the actual contact instruction value and the initial contact instruction value. 20. The shape memory alloy driving device according to claim 18, wherein the restraining member includes a first restraining member which restrains a movement of the movable portion over one of upper and lower limits of the moving range, and a second restraining member which restrains a movement of the movable portion over the other of the upper and lower limits of the moving range,the contact detecting section detects whether the movable portion is positioned to a first contact position where the movable portion is contacted with the first restraining member, and detects whether the movable portion is positioned to a second contact position where the movable portion is contacted with the second restraining member,the initial contact instruction value includes a first initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the first contact position, and a second initial contact instruction value which is predefined as an instruction value for positioning the movable portion to the second contact position,the actual contact instruction value includes a first actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the first contact position, and a second actual contact instruction value obtained when the contact detecting section has detected that the movable portion is positioned to the second contact position, andthe correcting section calculates the actual standby instruction value, based on the first initial contact instruction value, the second initial contact instruction value, the first actual contact instruction value, and the second actual contact instruction value.
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이 특허에 인용된 특허 (12)
Kosaka, Akira; Tanii, Junichi; Wada, Shigeru; Hara, Yoshihiro, Actuator control method and control device.
Yoshihiro Hara JP; Junichi Tanii JP; Shigeru Wada JP; Akira Kosaka JP, Control mechanism with actuator employing shape memory alloy and method for adjusting servo control of the control mechanism.
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