Calibration apparatus, calibration method, and manufacturing method for an electronic device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01C-025/00
G06F-019/00
G01C-019/00
G01P-021/00
출원번호
US-0291217
(2011-11-08)
등록번호
US-9476709
(2016-10-25)
우선권정보
JP-2010-261785 (2010-11-24)
발명자
/ 주소
Fukushima, Noriyuki
Osawa, Hiroshi
출원인 / 주소
Sony Corporation
대리인 / 주소
Dernier, Esq., Matthew B.
인용정보
피인용 횟수 :
0인용 특허 :
2
초록▼
Provided is a calibration apparatus, including: a holder for fixing an electronic device; a first motor for rotating the holder with a first rotation axis as a center; a second motor for rotating the holder with a second rotation axis perpendicular to the first rotation axis as a center; and a stopp
Provided is a calibration apparatus, including: a holder for fixing an electronic device; a first motor for rotating the holder with a first rotation axis as a center; a second motor for rotating the holder with a second rotation axis perpendicular to the first rotation axis as a center; and a stopper for restricting a rotational position of the holder about the second rotation axis to a range between a reference position and a perpendicular position reached by rotating the holder by 90 degrees from the reference position, in which the first motor rotates the holder to which the electronic device is fixed at a predetermined speed in each of states in which the rotational position of the holder about the second rotation axis falls in the reference position and in which the rotational position of the holder about the second rotation axis falls in the perpendicular position.
대표청구항▼
1. A calibration apparatus for calibrating a sensor of an electronic device, the sensor for detecting rotation of the electronic device in three-dimensional space and the sensor including orthogonal R-axis, P-axis, and T-axis directions, the calibration apparatus comprising: a holder defining orthog
1. A calibration apparatus for calibrating a sensor of an electronic device, the sensor for detecting rotation of the electronic device in three-dimensional space and the sensor including orthogonal R-axis, P-axis, and T-axis directions, the calibration apparatus comprising: a holder defining orthogonal X-axis, Y-axis, and Z-axis directions for the holder;a first motor for causing the holder to rotate at a predetermined rotational speed about a predetermined rotation axis;a second motor for causing the holder to rotate about the Y-axis;a Y-axis stopper for restricting a rotational position of the holder between a Y-axis reference position, a positive Y-axis perpendicular position positive 90 degrees from the Y-axis reference position about the Y-axis, and a negative Y-axis perpendicular position negative 90 degrees from the Y-axis reference position about the Y-axis,a third motor for causing the holder to rotate about the Z-axis;a Z-axis stopper restricting a rotational position of the holder between a Z-axis reference position, a positive Z-axis perpendicular position positive 90 degrees from the Z-axis reference position about the Z-axis, and a negative Z-axis perpendicular position negative 90 degrees from the Z-axis reference position about the Z-axis, wherein:the holder is operable to receive and retain the electronic device such that: (i) the R-axis of the sensor of the electronic device is coaxial with the X-axis of the holder, (ii) the P-axis of the sensor of the electronic device is coaxial with the Y-axis of the holder, and (iii) the T-axis of the sensor of the electronic device is coaxial with the Z-axis of the holder,the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that: (i) the holder is at the Y-axis reference position about the Y-axis, (ii) the holder is at the Z-axis reference position about the Z-axis, (iii) the X-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the X-axis, and the sensor of the electronic device to rotate about the R-axis, at the predetermined rotational speed to obtain first output values from the sensor,the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that: (i) the holder is at the Y-axis perpendicular position about the Y-axis, (ii) the holder is at the Z-axis reference position about the Z-axis, (iii) the Z-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the Z-axis, and the sensor of the electronic device to rotate about the T-axis, at the predetermined rotational speed to obtain second output values from the sensor, andthe second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that: (i) the holder is at the Y-axis reference position about the Y-axis, (ii) the holder is at the Z-axis perpendicular position about the Z-axis, (iii) the Y-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the Y-axis, and the sensor of the electronic device to rotate about the P-axis, at the predetermined rotational speed to obtain third output values from the sensor. 2. The calibration apparatus according to claim 1, further comprising a lock control portion operating to prevent the holder from rotating about the Y-axis when the rotational position of the holder is in the Y-axis reference position and in the Y-axis perpendicular position. 3. The calibration apparatus according to claim 1, wherein: the electronic device further comprises an acceleration sensor for detecting a magnitude of a gravitational acceleration applied thereto;when the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the X-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the Y-axis is vertical and axially aligned with a gravitational force to take a positive P-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative P-axis gravitational reading from the acceleration sensor;when the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the Z-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the X-axis is vertical and axially aligned with a gravitational force to take a positive R-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative R-axis gravitational reading from the acceleration sensor; andwhen the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the Y-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the Z-axis is vertical and axially aligned with a gravitational force to take a positive T-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative T-axis gravitational reading from the acceleration sensor. 4. A calibration method for calibrating a sensor of an electronic device, the sensor for detecting rotation of the electronic device in three-dimensional space and the sensor including orthogonal R-axis, P-axis, and T-axis directions, the calibration method comprising: providing a holder having orthogonal X-axis, Y-axis, and Z-axis directions;providing a first motor for causing the holder to rotate at a predetermined rotational speed about a predetermined rotation axis;providing a second motor for causing the holder to rotate about the Y-axis;providing a Y-axis stopper for restricting a rotational position of the holder between a Y-axis reference position, a positive Y-axis perpendicular position positive 90 degrees from the Y-axis reference position about the Y-axis, and a negative Y-axis perpendicular position negative 90 degrees from the Y-axis reference position about the Y-axis, providing a third motor for causing the holder to rotate about the Z-axis;providing a Z-axis stopper restricting a rotational position of the holder between a Z-axis reference position, a positive Z-axis perpendicular position positive 90 degrees from the Z-axis reference position about the Z-axis, and a negative Z-axis perpendicular position negative 90 degrees from the Z-axis reference position about the Z-axis;fixing the electronic device to the holder such that: (i) the R-axis of the sensor of the electronic device is coaxial with the X-axis of the holder, (ii) the P-axis of the sensor of the electronic device is coaxial with the Y-axis of the holder, and (iii) the T-axis of the sensor of the electronic device is coaxial with the Z-axis of the holder;causing the second motor, the third motor, the Y-axis stopper and the Z-axis stopper to rotate the holder such that: (i) the holder is at the Y-axis reference position about the Y-axis, (ii) the holder is at the Z-axis reference position about the Z-axis, (iii) the X-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the X-axis, and the sensor of the electronic device to rotate about the R-axis, at the predetermined rotational speed to obtain first output values from the sensor;causing the second motor, the third motor, the Y-axis stopper and the Z-axis stopper to rotate the holder such that: (i) the holder is at the Y-axis perpendicular position about the Y-axis, (ii) the holder is at the Z-axis reference position about the Z-axis, (iii) the Z-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the Z-axis, and the sensor of the electronic device to rotate about the T-axis, at the predetermined rotational speed to obtain second output values from the sensor; andcausing the second motor, the third motor, the Y-axis stopper and the Z-axis stopper to rotate the holder such that: (i) the holder is at the Y-axis reference position about the Y-axis, (ii) the holder is at the Z-axis perpendicular position about the Z-axis, (iii) the Y-axis is coaxial with the predetermined rotation axis, and (iv) the first motor causes the holder to rotate about the Y-axis, and the sensor of the electronic device to rotate about the P-axis, at the predetermined rotational speed to obtain third output values from the sensor. 5. The method of claim 4, further comprising writing calibration data calculated from the first, second and third output values to a nonvolatile memory of the electronic device. 6. The method of claim 4, further comprising locking the holder from rotating about the Y-axis when the rotational position of the holder is in the Y-axis reference position and in the Y-axis perpendicular position. 7. The method of claim 4, further comprising locking the holder from rotating about the Z-axis when the rotational position of the holder is in the Z-axis reference position and in the Z-axis perpendicular position. 8. The method of claim 4, wherein the electronic device further comprises an acceleration sensor for detecting a magnitude of a gravitational acceleration applied thereto, the method further comprising: when the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the X-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the Y-axis is vertical and axially aligned with a gravitational force to take a positive P-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative P-axis gravitational reading from the acceleration sensor;when the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the Z-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the X-axis is vertical and axially aligned with a gravitational force to take a positive R-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative R-axis gravitational reading from the acceleration sensor; andwhen the second motor, the third motor, the Y-axis stopper and the Z-axis stopper cause the holder rotate such that the Y-axis is coaxial with the predetermined rotation axis, the first motor causes: (i) the holder to rotate such that the Z-axis is vertical and axially aligned with a gravitational force to take a positive T-axis gravitational reading from the acceleration sensor, and (ii) the holder to rotate 180 degrees to take a negative T-axis gravitational reading from the acceleration sensor.
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이 특허에 인용된 특허 (2)
Bussmann Stephan A. (Granger IN) Ruggiero Joseph E. (Goshen IN) Trippel Christine G. (Mishawaka IN), Method and apparatus for making predetermined events with a biosensor.
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