JP2013093067A - Input device and data processing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an input device capable of easily performing screen scrolling or the like and to moderately provide an input device having a function for moving a cursor pointer in upper and lower directions and in right and left directions and a function for performing screen scrolling or the like.SOLUTION: An input device 101 includes a body part 100 having a longitudinal axis (SX1 axis: X axis), and a motion sensor part 111 (having an X-axis gyro sensor 110) for detecting rotation about the longitudinal axis of the body part 100. The input device can include a Y-axis gyro sensor and a Z-axis gyro sensor for detecting rotation about respective Y axis and Z axis perpendicular to each other in a plane perpendicular to the X axis.

Description

  The present invention relates to an input device, a data processing system, and the like.

  In recent years, an input that generates and outputs a physical quantity signal corresponding to the movement of the main body (housing) in space (including at least one of the posture of the main body (including rotation) and the movement of the main body (including translational movement)). There is a growing need for systems using devices (such as three-dimensional mice).

  A technique using a device (three-dimensional mouse) in which a cursor is moved on an image display device by moving a portable device in a three-dimensional space and is operated by a button is described in Patent Document 1, for example. ing.

  In Patent Document 1, two gyro sensors (angular velocity sensors) are used to detect rotational movements of two axes (Y axis and Z axis), and an input device that sends the detection signal as it is to the control device as operation information ( Pointing device). This input device can be used in place of a pointer or a laser pointer. For example, when the user shakes the front end of the main body (housing) of the input device while holding the input device in his / her hand, the position of the cursor on the display unit corresponds to the movement, for example. Move left and right.

JP 2001-56743 A

  For example, a mouse as a main pointing device has recently been provided with a scroll wheel (scroll dial). Thereby, not only the movement of the cursor pointer or the like but also the scrolling of the screen can be easily executed. By adding the scroll operation function to the mouse, for example, when a vertically long document is displayed, the screen can be easily scrolled up and down, and the convenience of the user is improved.

  On the other hand, when the screen is scrolled by an input device (such as a three-dimensional pointing device) equipped with a conventional motion sensor, the user places a cursor pointer on the scroll bar of the screen and performs a drag operation, for example. There is a need. Therefore, the user is required to perform very fine operations.

  It is also conceivable that an operation unit having a school wheel or the like is provided in the input device so that screen scrolling or screen zooming (magnification adjustment) can be performed by operating a dial or a switch. However, since the input device is used while being held by the user's hand in the space, it is difficult to stably operate the dial and the switch.

  Further, the input device is required to be small and lightweight so that it can be easily operated by hand. Therefore, the number of dials and switches that can be provided in the main body (housing) of the input device is practically about one. This hinders the multifunctionalization of the three-dimensional input device, for example.

  According to at least one embodiment of the present invention, it is possible to realize an input device capable of easily scrolling a screen. Further, for example, it is possible to easily give the input device a function of moving the cursor pointer up, down, left and right and a function of scrolling the screen. Therefore, for example, a pointing device with operability close to that of a mouse or an easy-to-use and multi-functional pointing device that has operability close to a pointer or laser pointer and can be easily scrolled. be able to.

  (1) One aspect of the input device of the present invention includes a main body having a longitudinal axis, and a motion sensor that detects rotation of the main body about the longitudinal axis.

  The motion sensor unit detects rotation around the longitudinal axis (long axis) of the main body (housing) of the input device having the longitudinal axis (long axis). The “longitudinal direction” of the main body (housing) is generally “the direction in which the main body (housing) extends (a direction extending linearly long)”, and the “longitudinal axis” is, for example, “longitudinal” “Axis matching direction”.

  The rotation of the main body (housing) can be detected, for example, by detecting the rotational angular velocity with a gyro sensor, and also detected by detecting the inclination of the main body around the longitudinal axis with an acceleration sensor. can do. The physical quantity signal output from the motion sensor unit can be used for movement control of the control target and other controls. For example, the scroll direction and scroll amount of the display screen can be controlled in accordance with the physical quantity signal, and for example, the zoom magnification of the display screen (or a specific part in the display screen) can also be controlled.

  As described above, since the input device is used in a state of being held by the user's hand in the space, it is difficult for the user to stably operate the dial and the switch. It is easy to rotate the casing) clockwise or counterclockwise with the longitudinal axis as the central axis. Therefore, according to this aspect, the user can easily perform, for example, scrolling or zooming the screen using the input device, and the usability of the input device is improved. In addition, since there is no need to provide a dial, a switch, or the like in the housing, the user interface of the input device can be simplified.

  In this specification, the expression of the direction (indicated direction or point direction) indicated by the tip of the main body (housing) in the space is also used. The indication direction (point direction) is determined by the posture of the main body (housing) in the space, and is conceptually distinguished from the longitudinal axis (axis determined by the shape of the housing). However, if the spatial coordinates are used as a reference, that is, if the orientation of the housing in the space is determined, as a result, the “longitudinal direction of the main body (housing)” and the “point direction of the main body (housing)” are It is considered that they match. Therefore, in this specification, when not related to the posture in the space of the main body (housing) of the input device, in principle, terms such as “longitudinal direction, longitudinal axis” are used and related to the posture in the space. Uses terms such as “indicated direction or point direction, X-axis (axis in a three-dimensional space that coincides with the point direction)” and the like. As described above, the “longitudinal axis, the point direction axis, and the X axis” can be treated as matching as a result.

  (2) In another aspect of the input device of the present invention, the motion sensor unit includes an X axis that coincides with a longitudinal axis of the main body unit, and a Y axis that is orthogonal to each other within a first plane perpendicular to the X axis. And an X-axis gyro sensor for detecting an angular velocity about the X-axis in a three-dimensional first orthogonal coordinate system determined by the Z-axis.

In this aspect, a three-dimensional orthogonal coordinate system defined by the X axis, the Y axis, and the Z axis is defined. The input device is provided with an X-axis gyro sensor that detects a rotational angular velocity around the X-axis. The angular velocity signal output from the X-axis gyro sensor can be used for movement control of the control target and other controls. For example, the scroll direction and scroll amount of the display screen can be controlled in accordance with the physical quantity signal, and for example, the zoom magnification of the display screen (or a specific part in the display screen) can also be controlled.

  (3) In another aspect of the input device of the present invention, the input device is used to determine a control amount related to a control target, and the input device receives a physical quantity signal from the motion sensor unit as the control amount. A physical quantity / control quantity conversion unit for converting into a control quantity signal indicating.

  An angular velocity signal or the like detected by a motion sensor unit provided in the input device can be directly transmitted as a control signal or the like to, for example, a data processing device. However, in this case, the data processing device controls the control amount of the control object on the display unit (for example, the displacement amount of the cursor pointer, the swing amount of the remotely operated camera, the screen scrolling) based on the received angular velocity signal. Amount, zoom magnification of the screen, and the like), and the burden on the data processing apparatus increases accordingly.

  Therefore, in this aspect, a physical quantity / control amount conversion unit is provided in the input device, and an angular velocity signal or the like is converted into a control amount of a control object in the display unit on the input device side. Then, the obtained control amount information (control amount signal) is transmitted to a data processing device or the like. As a result, the processing burden on the receiving side (data processing apparatus or the like) is reduced.

  (4) In another aspect of the input device of the present invention, the motion sensor unit includes a Y-axis gyro sensor that detects an angular velocity about the Y-axis, a Z-axis gyro sensor that detects an angular velocity about the Z-axis, And a second signal based on the angular velocity signal for the Y axis and the angular velocity signal for the Z axis, and a first signal processing unit that executes a first signal processing based on the angular velocity signal for the X axis. A second signal processing unit that executes processing.

  In order to detect the three-dimensional movement of the main body (housing) in the three-dimensional orthogonal coordinate system determined by the X axis, the Y axis, and the Z axis, the input device includes rotation around the Y axis and the Z axis, Each rotation around the X axis must be able to be detected independently. For this purpose, a signal processing system for detecting rotation around the Y axis and the Z axis and a signal processing system for detecting rotation around the X axis are necessary. Therefore, in this aspect, the input device executes a first signal processing unit that executes first signal processing based on the angular velocity signal for the X axis, and second signal processing based on angular velocity signals for the Y axis and the Z axis. And a second signal processing unit.

  For example, each of the first signal processing unit and the second signal processing unit can be realized by first hardware and second hardware (that is, different hardware). Further, for example, when common hardware is controlled by software (for example, when a CPU is used), a first signal processing unit and a second signal processing unit are prepared by preparing a signal processing routine for each signal processing unit. Each of the signal processing units can be realized.

  (5) In another aspect of the input device of the present invention, based on the priority processing determination unit that determines which of the first signal processing and the second signal processing should be prioritized, and the determination by the priority processing determination unit A priority selection unit having a selection unit that selectively outputs one of the first processing signal output from the first signal processing unit and the second processing signal output from the second signal processing unit, Also have.

As described in the above aspect (4), the rotation around the Y axis and the Z axis and the rotation around the X axis must be detected independently. In the above aspect (4), the first A signal processing unit and a second signal processing unit are provided. However, in reality, rotation about the Y axis and Z axis and rotation about the X axis may occur simultaneously. In other words, the user shakes the tip of the main body (housing) left and right and up and down slightly while supporting the main body (housing) of the input device by hand (that is, fine rotation about the Y axis and the Z axis). When the main body (housing) is rotated around the X axis, the rotation around the Y axis and the Z axis and the rotation around the X axis may occur at the same time. As long as the user operates the input device with the hand held in his / her hand, in reality, it is inevitable that some unnecessary rotation occurs against the user's intention.

  For example, when the user rotates the main body (housing) around the X axis in order to scroll the screen, rotation around the Y axis or around the Z axis occurs against the user's intention. Therefore, if a situation occurs in which the cursor pointer moves unexpectedly on the display screen, the operation accuracy and reliability of the input device are lowered.

  Therefore, when the situation where the first signal processing unit and the second signal processing unit operate simultaneously in parallel occurs, the input device determines which signal processing unit should be given priority and selects an output signal. It is more desirable to be able to. Therefore, in this aspect, a priority selection unit is provided in the input device. The priority selection unit includes any one of the first processing signal output from the first signal processing unit and the second processing signal output from the second signal processing unit based on the determination by the priority processing determination unit and the priority processing determination unit. And a selection unit that selectively outputs one of them. As a result, an operation unintended by the user is surely prevented, and a decrease in the operation accuracy and reliability of the input device is prevented.

  (6) In another aspect of the input device of the present invention, the motion sensor unit includes a Y-axis acceleration sensor that detects acceleration about the Y-axis, a Z-axis acceleration sensor that detects acceleration about the Z-axis, And the second signal processing unit performs coordinate conversion based on the Y-axis acceleration detected by the Y-axis acceleration sensor and the Z-axis acceleration detected by the Z-axis acceleration sensor. A coordinate transformation processing unit, wherein the coordinate transformation processing unit converts each of the Y-axis angular velocity detected by the Y-axis gyro sensor and the Z-axis angular velocity detected by the Z-axis gyro sensor perpendicular to the X-axis. U-axis angular velocity and V-axis angular velocity in a two-dimensional second orthogonal coordinate system determined by a U-axis that is a horizontal axis on the first surface and a V-axis that is an axis perpendicular to the U-axis on the first surface. The conversion of the each.

  As described in the above aspect (4), the rotation around the Y axis and the Z axis and the rotation around the X axis must be detected independently. In the above aspect (4), the first A signal processing unit and a second signal processing unit are provided. In the above aspect (5), a priority selection unit is further provided. However, in order to ensure the independence of the detection of the rotation around the Y axis and the Z axis and the detection of the rotation around the X axis, the rotation of the main body (housing) around the X axis is It is desirable not to affect the detection of rotation about the axis.

  For example, each of the angular velocity sensors corresponding to each axis is fixed to a plane (for example, an inner wall surface of the housing) provided in the main body portion of the input device. Therefore, if the main body (housing) of the input device rotates about the X axis, the Y axis and the Z axis rotate in the same manner, and the positions of the Y axis gyro sensor and the Z axis gyro sensor in the space also vary. There is a difference (error) between the angular velocity detected by each of the Y-axis angular velocity sensor and the Z-axis angular velocity sensor in the state where rotation about the X-axis occurs and the angular velocity detected in the state where no rotation occurs. .

Therefore, in this aspect, the rotation compensation process is performed and the detection signal is corrected to suppress the detection error. In this aspect, a two-dimensional YZ orthogonal coordinate system defined by the Y-axis and the Z-axis on the first surface perpendicular to the X-axis that matches the pointing direction of the main body is defined, and X that matches the pointing direction of the main-body A two-dimensional second orthogonal coordinate system (UV orthogonal coordinate system) defined by a U axis that is a horizontal axis on the first surface perpendicular to the axis and a V axis that is an axis perpendicular to the U axis on the first surface is defined. To do. The U axis is a horizontal axis in the first plane, and the V axis is a vertical axis orthogonal to the U axis in the first plane. Each of the U axis and the V axis is uniquely determined by specifying the pointing direction (point direction) of the main body, and is not affected by the rotation of the input device about the X axis.

  In this aspect, the coordinate conversion processing unit performs coordinate conversion (rotational coordinate conversion) from the YZ orthogonal coordinate system to the second orthogonal coordinate system (UV orthogonal coordinate system), and is detected by the Y-axis gyro sensor. Each of the Y-axis angular velocity and the Z-axis angular velocity detected by the Z-axis gyro sensor is converted into each of the U-axis angular velocity and the V-axis angular velocity. As a result, the angular velocity detected for each of the Y-axis and the Z-axis (when rotation about the X-axis occurs, an error associated with the rotation is included), but there is no rotation about the X-axis of the main body. Is corrected to an accurate angular velocity.

  In order to execute coordinate axis conversion (rotational coordinate conversion), it is necessary to detect the rotation angle between the X axis (Y axis) and the U axis (V axis) in the first plane orthogonal to the X axis. is there. Therefore, in this aspect, in addition to the Y-axis angular velocity sensor, a Y-axis acceleration sensor is provided as the physical quantity measuring device for the Y axis that is the detection axis, and the Z-axis angular velocity is used as the physical quantity measuring device for Z that is the detection axis. In addition to the sensor, a Z-axis acceleration sensor is provided. When the main body (housing) of the input device rotates about the X axis, which is the pointing direction axis, each of the acceleration detected for the Y axis and the acceleration detected for the Z axis varies according to the rotation angle. That is, the Y-axis acceleration and the Z-axis acceleration are expressed by equations that include the rotation angle in the first plane as a parameter (variable). Therefore, if the Y-axis acceleration and the Z-axis acceleration can be detected, information on the rotation angle can be obtained. By executing the rotation coordinate conversion based on the obtained rotation angle information, the Y-axis angular velocity and the Z-axis angular velocity can be converted into the U-axis angular velocity and the V-axis angular velocity.

  Therefore, according to this aspect, the rotation of the main body (housing) around the X axis does not affect the detection of the rotation around the Y axis and the Z axis. Therefore, according to this aspect, it is possible to ensure complete independence between detection of rotation around the Y axis and Z axis and detection of rotation around the X axis.

  (7) In another aspect of the input device of the present invention, the input device includes an operation unit including an output enable switch for switching permission / prohibition of signal output from the input device.

  In this aspect, the input device is provided with an operation unit (for example, a push-type or slide-type output enable switch) for switching permission / prohibition of signal output from the input device. Various variations are conceivable for the configuration of the operation unit. For example, when the input device has a cursor pointer movement control function (first control function) and a screen scroll function (second control function), an output enable switch can be provided for each function. It is also possible to provide a common output enable switch for commonly controlling function enable / disable. Since the operation of the output enable switch can be performed regardless of the posture of the main body (housing) in the space, it is easy for the user to operate the output enable switch.

  Only when the user is operating the operation unit (for example, only when the output enable switch is pressed), a signal is output from the input device. Therefore, in a period during which the operation unit is not operated (for example, a period in which the output enable switch is not pressed), even if the main body (housing) is moved, for example, position displacement of the control target (for example, cursor pointer) occurs. Absent. Therefore, according to this aspect, it is possible to reliably prevent the movement of the control target unintended by the user, and the usability of the input device is further improved.

  (8) In another aspect of the input device of the present invention, whether to execute the first processing by the first signal processing unit or to execute the second signal processing by the second signal processing unit is forcibly determined. An operation unit including a changeover switch for switching is provided.

  For example, the input device has a cursor pointer movement control function (first control function) and a screen scroll function (second control function), but the user wants to use only the first control function. There is also a possibility. Therefore, in this aspect, the input device is provided with a changeover switch for switching the function (signal processing type) so that any one of a plurality of functions of the input device can be selected. Thus, the user can select and use one function desired to be used from among a plurality of functions of the input device. Therefore, user convenience is further improved.

  (9) In another aspect of the input device of the present invention, the first processing signal output from the first signal processing unit is a control amount signal of a scroll amount of a display screen or a zoom magnification of a display image, The second processing signal output from the second signal processing unit is a control amount signal related to the displacement of the cursor pointer on the display screen.

  According to this aspect, the user can easily perform the scroll operation and zoom operation of the screen by rotating the main body (housing) of the input device around the X axis (longitudinal axis). The user can move the cursor pointer on the screen, for example, left, right, up, down, for example, by slightly swinging the tip of the main body (housing) left, right, up, down. Therefore, for example, a pointing device with operability close to that of a mouse or an easy-to-use and multi-functional pointing device that has operability close to a pointer or laser pointer and can be easily scrolled. be able to.

  (10) In one aspect of the data processing system of the present invention, any one of the input devices described above, a data processing device that receives a transmission signal of the input device and executes given data processing based on the received signal; including.

  By using at least one of the above aspects of the present invention, the usability of the three-dimensional input device is improved. Currently, a computer is often used for a three-dimensional space, and accordingly, a need for a highly convenient system using a three-dimensional input device capable of inputting a three-dimensional motion is increasing. According to this aspect, it is possible to realize a data processing system using a multi-functional and small-sized three-dimensional input device that is excellent in operability.

The figure which shows the structure of an example of the data processing system using an input device The figure which shows an example of an internal structure of the input device which detects the rotation around an X-axis The figure for demonstrating the usage example of the input device which detects the rotation around each axis | shaft of an X-axis, a Y-axis, and a Z-axis 4A to 4C are diagrams for explaining detection of a minute displacement in the Y-axis direction or the Z-axis direction of the distal end portion of the main body (housing) 100. FIG. 5A and 5B are diagrams showing an example of the internal configuration of the input device that detects rotation around the X, Y, and Z axes. 6A to 6C are diagrams for explaining a configuration for ensuring independence between rotation detection around the X axis and rotation detection around the Y axis and the Z axis. The figure which shows an example of a specific structure of the data processing system using the three-dimensional input device which detects the rotation about each axis | shaft of an X-axis, a Y-axis, and a Z-axis FIG. 8 is a flowchart showing the processing procedure of the priority selection unit. 9A to 9C are diagrams for explaining an angular velocity detection error due to rotation of the input device with respect to the X axis. Diagram for explaining the contents of coordinate transformation (rotational coordinate transformation) 11A to 11E are diagrams for explaining information and the like necessary for coordinate conversion. Diagram for explaining information necessary for coordinate transformation Flow chart showing an example of processing sequence of coordinate transformation processing for rotation compensation The figure which shows the example of the external appearance structure of the other example (example which provides an output enable switch) of the input device which detects the rotation around the X-axis, the rotation around the Y-axis, and the rotation around the Z-axis The figure which shows the example of an external appearance structure of the other example (example which provides an enable switch etc.) of the input device which detects the rotation around the X-axis, the rotation around the Y-axis, and the rotation around the Z-axis. The figure which shows the example of the external appearance structure of the other example (example which provides a some enable switch) of the input device which detects the rotation around the X-axis, the rotation around the Y-axis, and the rotation around the Z-axis. The figure which shows the internal structure of the other example (example which provides a function change switch) of the input device which detects the rotation around the X-axis, the rotation around the Y-axis, and the rotation around the Z-axis.

  Next, embodiments of the present invention will be described with reference to the drawings. Note that the present embodiment described below does not unduly limit the contents of the present invention described in the claims, and all the configurations described in the present embodiment are as means for solving the present invention. It is not always essential.

(First embodiment)
(Example of Use of Three-Dimensional Input Device) FIG. 1 shows a data processing system using an input device (three-dimensional input device: here, for example, a pointing device that can be used instead of a mouse or a laser pointer). It is a figure which shows the structure of an example.

  In FIG. 1, the input device 101, the data processing device 200 (having the wireless antenna AN2), and the display device 300 constitute a data processing system. The input device 101 and the data processing device 200 transmit and receive signals (information) by communication (in this case, wireless communication, but not limited to this may be wired communication or optical communication). It can be carried out.

  The input device 101 has a longitudinal axis (long axis) SX1 and a motion sensor unit (not shown in FIG. 1). The motion sensor unit includes, for example, a gyro sensor, an acceleration sensor, and the like, and can detect the rotation of the main body (housing) 100 of the input device 101 around the longitudinal axis (long axis) SX1. The physical quantities (rotational angular velocity, acceleration, etc.) generated by rotation around the longitudinal axis (long axis) SX1 are the control of the scroll amount of the display screen and the change of the zoom magnification of the display screen (or a designated area in the display screen). It can be used for control.

  In the example surrounded by a dotted line on the upper side of FIG. 1, a map in Tokyo ward is displayed by the display device 300 on, for example, a screen or a display. The user holds the main body (housing) 100 of the input device 101 and rotates the main body (housing) 100 about the longitudinal axis SX1 by θ (SX1) in the direction of the arrow in the figure ( Here, the direction of the arrow in the figure is the positive direction).

  Then, for example, the display screen PT1 is scrolled upward. When the user rotates the main body (housing) 100 in the negative direction, the display screen PT1 is scrolled downward. Further, for example, the zoom magnification of the designated area M in the display screen PT2 is increased, and the image is enlarged. When the user rotates the main body (housing) 100 in the negative direction, the zoom magnification for the designated area M in the display screen PT2 is reduced, and the image is reduced.

As described above, since the main body (housing) 100 of the input device 101 is used in a state of being held by the user's hand in the space, the user can stably operate the dial and the switch. Although difficult, it is easy for the user to rotate the main body (housing) 100 clockwise or counterclockwise about the longitudinal axis SX1 as a central axis. Therefore, in the data processing system shown in FIG. 1, the user can easily perform, for example, scrolling or zooming the screen using the input device 101, and the usability of the input device 101 is remarkably improved. In addition, since there is no need to provide a dial, a switch, or the like in the housing, the user interface of the input device can be simplified.

  The input device 101 in FIG. 1 has, for example, a cylindrical appearance. The main body (housing) 100 of the input device 101 has a longitudinal axis (long axis) SX1 and a short axis SX2 (an axis perpendicular to the longitudinal axis SX1 and shorter in length than the longitudinal axis). The “longitudinal direction” is, for example, “a direction in which the main body (housing) 100 extends linearly (a direction in which the body 100 extends linearly long)”.

  In FIG. 1, a line segment connecting the center point C1 of the upper surface A of the cylindrical main body (housing) 100 and the center point C2 of the bottom surface C2 is assumed, and an axis coinciding with this line segment is defined as a longitudinal axis SX1. Yes. The top surface A and the bottom surface B can also be regarded as a vertical cross section of the housing. For example, the “axis that coincides with the normal of the center point of the vertical cross section of the housing and coincides with the longitudinal direction” is defined as the longitudinal axis SX1. can do.

  The longitudinal direction axis SX1 coincides with the X axis (point direction axis) set in the space. The point direction (indicated direction) is “the direction indicated by the tip of the main body (housing) located in the space”. The “point direction” is determined by the posture of the main body (housing) in the space and is conceptually distinguished from the longitudinal axis (axis determined by the shape of the housing). However, if the spatial coordinates are used as a reference, as a result, the “longitudinal direction of the main body (housing)” and the “point direction of the main body (housing)” are considered to coincide. Therefore, in this specification, when not related to the posture in the space of the main body (housing) of the input device, in principle, terms such as “longitudinal direction, longitudinal axis” are used and related to the posture in the space. Uses terms such as “indicated direction or point direction, X-axis (axis in a three-dimensional space that coincides with the point direction)” and the like. As described above, the “longitudinal axis, the point direction axis, and the X axis” can be handled as matching as a result.

(Internal configuration example of input device that detects rotation around X axis)
FIG. 2 is a diagram illustrating an example of an internal configuration of an input device that detects rotation around the X axis. The input device 101 in FIG. 2 includes a motion sensor unit 111. The motion sensor unit 111 and the X axis that coincide with the longitudinal axis SX1 of the main body (housing) 100 and the plane perpendicular to the X axis are mutually connected. An X-axis gyro sensor 110 that detects a rotational angular velocity about the X-axis in a three-dimensional orthogonal coordinate system determined by the orthogonal Y-axis and Z-axis is provided.

  The input device 101 further includes an amplifier 519, an A / D converter 528, a conversion processing unit (CPU or the like) 534, a transmission unit (communication unit) 536, and an antenna AN1. The conversion processing unit (CPU or the like) 101 is provided with a coefficient calculation unit 534 as a physical quantity / control amount conversion unit. The coefficient calculation unit 534 converts the angular velocity signal into a displacement amount signal, for example, by multiplying the angular velocity signal by a conversion coefficient.

  In FIG. 2, a three-dimensional orthogonal coordinate system defined by the X axis, the Y axis, and the Z axis is defined in space, and the input device 101 includes an X axis gyro sensor for detecting a rotational angular velocity around the X axis. 110 is provided. The angular velocity signal ωx output from the X-axis gyro sensor 110 is used for movement control of a control target (for example, cursor poi), other control (scroll control of a screen to be controlled, zoom of a screen to be controlled or a specific area) (Magnification change control). That is, for example, the scroll direction and the scroll amount of the display screen can be controlled in accordance with the physical quantity signal, and for example, the zoom magnification of the display screen (or a specific portion in the display screen) can also be controlled. .

  The angular velocity signal ωx detected by the motion sensor unit 111 (X-axis gyro sensor 110) can be directly transmitted as a control signal or the like to, for example, the data processing device 200 (see FIG. 1). However, in this case, the data processing device 200 controls the control amount of the control object (for example, the amount of displacement of the cursor pointer, the remote operation of the remotely operated camera, etc.) on the display device 300 (see FIG. 1) based on the received angular velocity signal. It is necessary to calculate a head swing amount, a screen scroll amount, a screen zoom magnification, and the like, and the burden on the data processing apparatus increases accordingly.

  Therefore, in FIG. 2, the input device 101 is provided with a coefficient calculation unit 534 as a physical quantity / control amount conversion unit, and the input device 101 side converts the angular velocity signal ωx into a control amount of a control object in the display device 300. . Then, the obtained control amount information (control amount signal) is transmitted to the data processing device 200. As a result, the processing load on the receiving side (data processing apparatus 200) is reduced.

  (Example of use and internal configuration of input device for detecting rotation around X axis, Y axis, and Z axis) In the input device of FIG. 2, only rotation around the X axis is detected. If the input device can detect not only rotation around the X axis but also rotation around the Y axis and rotation around the Z axis, more information can be input. Hereinafter, an input device that detects rotation around each of the X, Y, and Z axes will be described.

  FIG. 3 is a diagram for explaining an example of use of the input device that detects rotation around each of the X, Y, and Z axes. In FIG. 3, a three-dimensional orthogonal coordinate system defined by an X axis that coincides with the longitudinal axis SX1 of the main body (housing) 100 and a Y axis and a Z axis that are orthogonal to each other in a plane perpendicular to the X axis is defined. Is done. The input device 101 detects rotation about each of the three axes of the main body (housing) 100.

  In FIG. 3, the input device 101 is used instead of a laser pointer. A screen 410 is displayed on the screen 400. The screen 410 can be scrolled up and down. In addition, the cursor pointer CP moves up, down, left and right on the screen 410. In FIG. 3, the vertical and horizontal movement of the cursor pointer CP is controlled by the user slightly displacing the tip of the main body (housing) 100 in the Y-axis direction or the Z-axis direction. Further, the vertical scrolling of the screen 410 is controlled by the rotation of the main body (housing) 100 around the X axis.

  4A to 4C are diagrams for explaining detection of minute displacements in the Y-axis direction or the Z-axis direction of the distal end portion of the main body (housing) 100. FIG.

  As shown in FIG. 4A, in the X axis that coincides with the indicated direction (point direction) of the main body (housing) 100 of the input device 101 and the Q plane that is the first surface perpendicular to the X axis. A Y-axis and a Z-axis that are orthogonal to each other define a first orthogonal coordinate system in a three-dimensional space. The X axis is a first detection axis, the Y axis is a second detection axis, and the Z axis is a third detection axis.

  If the posture of the input device 101 in the space of the main body (housing) 100 is specified, the first orthogonal coordinate system is uniquely determined. The first orthogonal coordinate system is not a fixed coordinate system, and the main body (housing) of the input device 101 is rotated by θ (X) about the X axis as shown by a dotted line in FIG. Along with this, the Y-axis and the Z-axis also rotate by θ (X). Note that θ (X) represents a rotation angle of rotation about the X axis as a rotation axis.

As shown in FIG. 4B, the minute movement in the vertical direction (vertical direction) of the main body (housing) 100 of the input device 101 is a rotation (rotation angle θ (Y)) about the Y axis. Can be detected as In FIG. 4B, the main body (housing) 100 of the input device 101 is drawn in a rectangular parallelepiped shape for convenience. This rectangular parallelepiped shape can be seen as indicating the inner wall surface of a housing to which a motion sensor (angular velocity sensor or the like) is attached, for example. Therefore, if the rotational angular velocity about the Y axis is detected by the Y-axis angular velocity sensor and the angular velocity is integrated over time, information on the rotational angle θ (Y) regarding the Y axis can be obtained. That is, the vertical movement of the main body (housing) 100 of the input device 101 can be detected.

  Also, as shown in FIG. 4C, the minute movement of the main body (housing) 100 of the input device 101 from side to side (horizontal direction) is caused by rotation about the Z axis (rotation angle θ (Z )) Can be detected. Therefore, if the rotational angular velocity about the Z axis is detected by the Z-axis angular velocity sensor and the angular velocity is integrated over time, information on the rotational angle θ (Z) regarding the Z axis can be obtained. That is, it is possible to detect left and right movements of the main body (housing) 100 of the input device 101.

  5A and 5B are diagrams illustrating an example of an internal configuration of an input device that detects rotation around the X axis, the Y axis, and the Z axis. FIG. 5A shows a state where the casing does not rotate around the X axis, and FIG. 5B shows a state where the casing rotates around the X axis (rotation angle θ2).

  The input device 101 includes an X-axis gyro sensor 110 that detects a rotational angular velocity ωx around the X axis, a Y-axis gyro sensor 102 that detects a rotational angular velocity ωy around the Y axis, and a Z that detects a rotational angular velocity ωz around the Z axis. An axis gyro sensor 104, a Y axis acceleration sensor 106 that detects acceleration in the Y axis direction, and a Z axis acceleration sensor 108 that detects acceleration in the Z axis direction are included. Each of the X-axis gyro sensor 110, the Y-axis gyro sensor 102, and the Z-axis gyro sensor 104 has an angular velocity in the direction of the arrow of each axis (the counterclockwise direction in FIGS. 5A and 5B). In contrast, a positive value is output, and the Y-axis acceleration sensor 106 and the Z-axis acceleration sensor 108 output a positive value with respect to the acceleration in the direction of the arrow of each axis.

  In FIG. 5B, in the Q plane, which is the first plane perpendicular to the X axis, the U axis that is the horizontal axis and the V axis that is perpendicular to the U axis (vertical axis) Two orthogonal coordinate systems are defined. This point relates to a coordinate conversion process for rotation compensation. This point will be described later.

  (Description of independence between rotation detection around the X axis and rotation detection around the Y axis and the Z axis) In order to detect the three-dimensional movement of the (housing) 100, the input device 101 must be able to independently detect rotation about the Y axis and Z axis and rotation about the X axis.

  For this purpose, as the configuration of the signal processing unit, for example, it is preferable to adopt a configuration as shown in FIG. 6 (A) to FIG. 6 (C).

  FIGS. 6A to 6C are diagrams for explaining a configuration for ensuring independence between rotation detection around the X axis and rotation detection around the Y axis and the Z axis.

  6A, the input device 101 includes a first signal processing unit 531 that performs first signal processing based on the angular velocity signal ωx for the X axis, and angular velocity signals ωy, ωz (for the Y axis and the Z axis). And a second signal processing unit 533 that executes second signal processing based on the acceleration signals γy, γz). The first signal processing unit 531 outputs a second processing signal SGa, and the second signal processing unit 533 outputs a second processing signal SGb.

That is, in order to ensure the independence of the first signal processing and the second signal processing, a signal processing system for detecting rotation about the Y axis and the Z axis and a signal for detecting rotation about the X axis It is necessary to provide a processing system.

  For example, each of the first signal processing unit 531 and the second signal processing unit 533 can be realized by first hardware and second hardware (that is, different hardware). Further, for example, when common hardware is controlled by software (for example, when a CPU is used), by preparing a signal processing routine for each signal processing unit, the first signal processing unit 531 and the first signal processing unit 531 Each of the two signal processing units 533 can be realized.

  In FIG. 6B, a priority selection unit 543 is further provided. The priority selection unit 543 includes a priority processing determination unit E1 that determines which of the first signal processing and the second signal processing should be prioritized, and a first signal processing unit 531 based on the determination by the priority processing determination unit E1. And a selection unit E2 that selectively outputs one of the first processing signal output from the second processing signal and the second processing signal output from the second signal processing unit 533.

  As long as the input device 101 is held in space by the user's hand, in reality, rotation about the Y axis and Z axis and rotation about the X axis may occur simultaneously. That is, the user shakes the tip of the main body (housing) 100 from side to side and up and down with the main body (housing) of the input device supported by hand (that is, the Y axis and the Z axis are minute). When the main body (housing) 100 is rotated around the X axis, the rotation around the Y axis and the Z axis and the rotation around the X axis may occur simultaneously. . As long as the user operates the input device with the hand held in his / her hand, in reality, it is inevitable that some unnecessary rotation occurs against the user's intention.

  For example, when the user rotates the main body (housing) around the X axis in order to scroll the screen, rotation around the Y axis or around the Z axis occurs against the user's intention. Therefore, if a situation occurs in which the cursor pointer moves unexpectedly on the display screen, the operation accuracy and reliability of the input device 101 are lowered.

  Therefore, when the situation where the first signal processing unit 531 and the second signal processing unit 533 operate simultaneously in parallel occurs, the input device 101 determines which signal processing unit should be given priority and outputs the output signal. It is more desirable to be able to select.

  Therefore, in FIG. 6B, a priority selection unit 543 is provided in the input device 101. The priority selection unit 543 includes a priority processing determination unit E1 and a first processing signal output from the first signal processing unit and a second processing signal output from the second signal processing unit based on the determination by the priority processing determination unit. And a selection unit E2 that selectively outputs any one of the above. As a result, an operation unintended by the user is surely prevented, and a decrease in the operation accuracy and reliability of the input device is prevented.

  In FIG. 6C, a rotation compensation unit (coordinate conversion processing unit) 532 is further provided. In order to ensure the independence of the detection of the rotation around the Y axis and the Z axis and the detection of the rotation around the X axis, the rotation of the main body (housing) 100 around the X axis requires the rotation of the Y axis and the Z axis. It is desirable not to affect the detection of the surrounding rotation.

  For example, each of the angular velocity sensors 102, 104, and 110 corresponding to each axis is fixed to a plane (for example, an inner wall surface of the casing) provided in the main body (housing) 100 of the input device 101. Therefore, if the main body (housing) 100 of the input device 101 rotates about the X axis, the Y axis and the Z axis rotate in the same manner, and the positions of the Y axis gyro sensor and the Z axis gyro sensor in the space also vary. There is a difference (error) between the angular velocity detected by each of the Y-axis angular velocity sensor 102 and the Z-axis angular velocity sensor 104 when rotation about the X-axis occurs and the angular velocity detected when rotation does not occur. Exists.

  Therefore, in FIG. 6C, a rotation compensation process is performed to correct the detection signal, thereby suppressing a detection error. That is, as shown in FIG. 5B, the two-dimensional YZ orthogonality determined by the Y axis and the Z axis in the first plane perpendicular to the X axis that coincides with the point direction of the main body (housing) 100. A coordinate system is defined, and a U axis that is a horizontal axis in the first plane perpendicular to the X axis that coincides with the point direction of the main body (housing) 100, and an axis that is perpendicular to the U axis in the first plane A two-dimensional second orthogonal coordinate system (UV orthogonal coordinate system) defined by a certain V axis is defined. The U axis is a horizontal axis in the first plane, and the V axis is a vertical axis orthogonal to the U axis in the first plane. Each of the U axis and the V axis is uniquely determined by specifying the pointing direction (point direction) of the main body (housing), and is not affected by the rotation of the input device 101 about the X axis. The Y-axis angular velocity ωy detected by the Y-axis gyro sensor 102 and the Z-axis gyro sensor 104 are detected by coordinate conversion (rotational coordinate conversion) from the YZ orthogonal coordinate system to the second orthogonal coordinate system (UV orthogonal coordinate system). Each of the Z-axis angular velocities ωz to be converted is converted into each of the U-axis angular velocities ωu and the V-axis angular velocities ωv. As a result, the angular velocities detected for each of the Y-axis and the Z-axis (when rotation about the X-axis occurs, an error associated with the rotation is included) for the X-axis of the main body (housing) 100. It is corrected to an accurate angular velocity in a state where there is no rotation. Therefore, according to the configuration of FIG. 6C, the rotation of the main body (housing) around the X axis does not affect the detection of the rotation around the Y axis and the Z axis. Therefore, according to the configuration of FIG. 6C, complete independence between detection of rotation around the Y axis and Z axis and detection of rotation around the X axis can be ensured. Details of the rotation compensation process (rotation coordinate conversion) will be described later with reference to FIGS.

  (Example of a specific configuration of a system using a three-dimensional input device that detects rotation about each of the X, Y, and Z axes) FIG. 7 illustrates each of the X, Y, and Z axes. It is a figure which shows an example of a specific structure of the data processing system which uses the three-dimensional input device which detects rotation of this. The input device shown in FIG. 7 employs the configuration shown in FIG.

  The input device 101 (here, a three-dimensional pointing device) includes a motion sensor unit (three-dimensional motion sensor unit) 502. The motion sensor unit 502 includes an X-axis gyro sensor 110, a Y-axis gyro sensor 102, a Z-axis gyro sensor 104, a Y-axis acceleration sensor 106, and a Z-axis acceleration sensor 108. The Y-axis acceleration sensor 106 and the Z-axis acceleration sensor 108 are provided for rotation compensation processing (rotation coordinate conversion).

  The input device (pointing device) 101 further includes amplifiers 512 to 518 and 519 for amplifying output signals of the sensors 102 to 110, A / D converters 520 to 526 and 528, and a conversion processing unit (for example, CPU) 530. And a comparison / determination unit 540, a selection signal generation unit 541, a selector 535, a wireless transmission unit 536, and an antenna AN1.

  The comparison determination unit 540 and the selection signal generation unit 541 constitute a priority processing determination unit E1 in FIG. The selector 535 corresponds to the selection unit E2 in FIG.

  The conversion processing unit 530 includes a coordinate conversion processing unit 532 and coefficient calculation units (physical quantity / control amount conversion units) 534a and 534b. The coefficient calculation units (physical quantity / control quantity conversion units) 534a and 534b may not be provided. In this case, the angular velocity signals (ωu (or ωy), ωv (or ωz), ωx,) after coordinate conversion are output.

The data processing device 600 includes an antenna AN2, a receiving unit 610, a data processing unit (for example, CPU) 620, a ROM 630, a RAM 640, a display control unit 650, and a display unit 660. The display unit 660 may include a display 662. When the display unit 660 is a projection display device, an image is displayed on the screen 400, for example.

  The input device 101 in FIG. 7 can be used to input information for determining the displacement direction and displacement amount of the control target (for example, the cursor pointer CP) to the data processing device 600. A coefficient calculation unit 534 as a physical quantity / control amount conversion unit provided in the input device 101 multiplies the angular velocity signal output from the coordinate conversion processing unit 532 by a coefficient (conversion coefficient), for example, a control target (cursor pointer) CP, etc.) is converted into a displacement amount signal (control amount signal in a broad sense) for specifying a displacement amount (control amount in a broad sense). That is, for example, the angular velocity signals ωu and ωv after coordinate conversion are converted into displacement amount signals Mh and Mv (Mh is a displacement amount in the horizontal direction and Mv is a displacement amount in the vertical direction), respectively. Further, the angular velocity signal ωx after the coordinate conversion is converted into a displacement amount Ms indicating the scroll amount of the screen. Details of the coordinate conversion process will be described later.

  The angular velocity signal for each axis detected by the motion sensor unit 502 provided in the input device 101 can be transmitted as it is to the data processing device as a control signal or the like. However, in this case, it is necessary for the data processing device 600 to calculate the amount of displacement of the controlled object (for example, the cursor pointer CP) on the display unit 660 based on the received angular velocity signal, and accordingly, the data processing device 600 The burden of increases. Therefore, in FIG. 7, the input device 101 is provided with a coefficient calculation unit 534 serving as a physical quantity / control amount conversion unit, and the angular velocity signal is displayed on the input device 101 side as an object to be controlled (for example, a cursor pointer CP or a display). Screen) control amount (cursor movement amount or screen scroll amount). Then, each of the obtained variable control amount information (control amount signals) Mh, Mv, and Ms is transmitted to the data processing device 600 by wireless communication (not limited to this, but may be optical communication or wired communication). Send. As a result, the processing burden on the data processing apparatus 600 is reduced.

  In addition, the coordinate conversion processing unit 532 prohibits output of a signal according to the movement of the main body when the pointing direction (point direction) of the front end of the main body (housing) is directly above or directly below. Alternatively, the coordinate conversion process is stopped, and each of the Y-axis angular velocity signal ωy and the Z-axis angular velocity signal ωz before the coordinate conversion process is output as it is.

  The operation of the priority selection unit (reference numeral 543 in FIG. 6C) including the comparison determination unit 540, the selection signal generation unit 541, and the selector 535 in FIG. 7 will be described later.

  Further, the data processing unit 620 of the data processing device 600 performs given data processing based on the signal received by the receiving unit 610, and generates, for example, image display data and a timing control signal. The display control unit 650 controls image display on the display unit 660.

  In the data processing system of FIG. 7, a transmission unit 536 is provided in the input device, and a physical quantity signal can be freely transmitted from the input device 101 to the data processing device or the like by wireless communication (including optical communication). Therefore, the usability of the input device is improved. Note that the input device 101 can also output a signal by wired communication.

  According to the present embodiment, a data processing system using a small three-dimensional input device with excellent operability can be realized. Next, a processing procedure of the priority selection unit (reference numeral 543 in FIG. 6C) including the comparison determination unit 540, the selection signal generation unit 541, and the selector 535 in FIG. 7 will be described.

  (Processing Procedure of Priority Selection Unit) FIG. 8 is a flowchart showing the processing procedure of the priority selection unit. The priority selection unit (reference numeral 543 in FIG. 6C) includes a comparison determination unit 540, a selection signal generation unit 541, and a selector 535 in FIG. When the rotation around the X axis and the rotation around the Y axis or the Z axis occur simultaneously in parallel, the priority selection unit 543 determines which is the rotation according to the user's intention, and either one of the processes Select with priority.

  First, the comparison determination unit 540 in FIG. 7 takes in angular velocity data ωx, ωy, ωz for each of the X axis, the Y axis, and the Z axis (step S150).

  Next, the comparison / determination unit 540 performs threshold determination in order to prevent detection of noise caused by minute shaking of the housing (step 151).

  That is, as shown in FIG. 8, it is determined whether or not the absolute value of the angular velocity ωx around the X axis is larger than a threshold value Cx for rotation around the X axis. Is adopted, and the adopted signal is stored as J (x). If it is small, the acquired ωx is discarded.

  Also, it is determined whether or not the square root of the sum of the square of ωy and the square of ωz is larger than a threshold value Cyz for rotation around the Y axis or the Z axis. Adopted as a target signal, the above-mentioned square root signal is stored as J (yz), and when it is small, the acquired ωy and ωz are discarded.

  Next, the comparison determination unit 540 executes a correction coefficient multiplication process (step S152). That is, the normal angular velocity due to rotation (twisting) around the X-axis of the main body (housing) 100 is, for example, about several tens of degrees / second, whereas the tip of the main body (housing) 100 is Y The normal angular velocity around the Y-axis and Z-axis caused by minutely shaking in the axis and Z-axis directions is, for example, about several degrees / second. That is, since the scale of the rotation amount is originally different, when J (x) and J (yz) are directly compared, J (x)> J (yz) is always obtained, and proper comparison processing cannot be performed. Therefore, J (x) is multiplied by a given correction coefficient Kx to reduce the value of J (x) by a predetermined ratio, and J (yz) is multiplied by a given correction coefficient Kyz to obtain J (x The value of (yz) is increased at a predetermined rate.

  Next, the comparison determination unit 540 compares KxJ (x) and KyzJ (yz) (step S153). If KxJ (x)> KyzJ (yz), the selection signal generation unit 541 in FIG. 7 sets the selection signal SEL to the first level, so that the selector 535 corresponds to the angular velocity ωx around the X axis or the same. A control amount (for example, screen scroll amount Ms) is selected and output (step S154).

  Further, if KxJ (x) <KyzJ (yz), the selection signal generation unit 541 in FIG. 7 sets the selection signal SEL to the second level, whereby the selector 535 causes the angular velocity ωy, ωz or a control amount (horizontal displacement amount Mh, vertical displacement amount MV of the cursor) corresponding to this is selected and output (step S155).

  As a result, even when rotation about the X axis and rotation about the Y axis or the Z axis occur simultaneously, an operation unintended by the user is surely prevented, and a decrease in the operation accuracy and reliability of the input device 101 is prevented. The

  (Description of Coordinate Conversion for Rotation Compensation) The coordinate conversion processing for rotation compensation by the coordinate conversion processing unit 532 in FIG. 7 will be described below.

FIG. 9A to FIG. 9C are diagrams for explaining the detection error of the angular velocity due to the rotation about the X axis of the input device. As shown in FIG. 9A, it is assumed that the right end of the main body (housing) 100 of the input device 101 is facing (pointing) diagonally upward to the right. FIG. 9B illustrates a cross section taken along line SS ′ of FIG. 9A in a state where the main body (housing) 100 of the input device 101 is not rotated with respect to the X axis. FIG. 9C shows a cross section taken along line SS ′ of FIG. 9A in a state in which the main body (housing) 100 of the input apparatus 101 is rotated by θ2 with respect to the X axis.

  As shown in FIGS. 9B and 9C, the cross section of the inner wall surface of the main body (housing) 100 of the input device 101 is substantially square. Four surfaces constituting the inner wall surface (or each side constituting the cross-sectional shape of the inner wall surface) are defined as P1 to P4. The two gyro sensors (angular velocity sensors) 102 and 104 detect rotational angular velocities about the Y axis and the Z axis (that is, the detection axis), respectively. The gyro sensors 102 and 104 are fixed to inner wall surfaces P3 and P2 of the main body (housing) 100 of the input device 101, respectively. Therefore, as shown in FIG. 9C, if the main body (housing) 100 of the input device 101 rotates about the axis (X axis) other than the detection axis (Y axis, Z axis) by θ2, the Y axis , And the Z axis rotate in the same manner, and as a result, the position of each gyro sensor (angular velocity sensor) varies.

  Therefore, even when the same movement (here, left and right movements QR and QL) occurs in the distal end portion of the main body (housing) 100 of the input device 101, the rotation around the X axis does not occur (see FIG. 9 (B)) and the angular velocity detected in the state where the rotation about the X axis has occurred (the state of FIG. 9C). That is, a detection error occurs due to the rotation of the main body (housing) 100 of the input device 101 about an axis (X axis) other than the detection axis (Y axis, Z axis).

  Therefore, in the present embodiment, by executing correction (specifically, coordinate conversion) of the detected angular velocities (angular velocities about the Y axis and the Z axis), it is affected by the rotation of the casing around the X axis. It is always possible to detect an accurate angular velocity. This eliminates restrictions on how the user holds the main body (housing), and improves the operability of the three-dimensional input device. In order to execute the coordinate transformation, it is necessary to obtain information about the rotation angle around the X axis. For this reason, the input device of the present embodiment detects acceleration around the Y axis and acceleration around the Z axis. An acceleration sensor is provided.

(Coordinate conversion process)
The input device 101 is provided with a coordinate conversion processing unit 532, and the coordinate conversion processing unit 532 executes coordinate conversion processing. Hereinafter, the coordinate conversion process will be described with reference to FIGS.

  FIG. 10 is a diagram for explaining the contents of coordinate transformation (rotational coordinate transformation). FIGS. 11A to 11E and FIG. 12 are diagrams for explaining information necessary for coordinate conversion. Coordinate conversion is generally realized by a combination of parallel movement and rotation. In this embodiment, only the rotation about the X axis needs to be considered. The rotation coordinate transformation can be realized by matrix calculation using a rotation matrix.

Here, when the Y-axis acceleration is γ _y , the Z-axis acceleration is γ _z , the Y-axis angular velocity is ω _y , and the Z-axis acceleration is ω _z , the coordinate conversion processing unit 532 has the following equation (1) and Each of the Y-axis angular velocity ω _y and the Z-axis angular velocity ω _z is converted into each of the U-axis angular velocities ω _u and ω _v by the calculation of equation (2). Hereinafter, it will be described in order. When the angle formed by the Y axis (Z axis) and the U axis (V axis) on the Q plane perpendicular to the X axis (see FIG. 4A) is θ2, the Y axis angular velocity ω _y and the Z axis angular velocity ω _z In order to convert each of these into U-axis angular velocities ω _u and ω _v , a matrix operation of the following equation (3) may be performed. Therefore, the following expressions (4) and (5) are established.

  The coordinate conversion processing unit 532 shown in FIG. 10 executes the calculations shown in the above equations (4) and (5). However, in order to execute the calculations of the equations (4) and (5), it is necessary to know sin θ2 and cos θ2, and for this reason, in this embodiment, the Y-axis acceleration sensor 106 and the Z-axis acceleration sensor 108 are Is provided.

  Here, gravity acceleration will be described with reference to FIGS. 11 (A) to 11 (E). As shown in FIG. 11A, the gravity acceleration (vertical upward direction) is G. That is, in a weightless state (for example, a state where an object is placed in outer space), the output of the acceleration sensor is zero. Similarly, since the inside of the free-falling object is also in a weightless state, the output of the acceleration sensor is zero. On the other hand, free fall on the earth means that the object is accelerating downward by 1G (upward by -1G). Further, a relationship of (acceleration sensor output) = (acceleration state of object) − (downward 1G) is established. Therefore, when the object is stationary, the output of the acceleration sensor = 0− (downward 1G) = (upward 1G) is established. In addition, when the vertical axis (G axis) and the first surface form θ1, the gravity acceleration (vertically upward) G is the vertical axis in the first surface, the V axis (the X axis is not rotated) Let G1 (= Gcos θ1) be the component for the Z axis in FIG.

  As shown in FIG. 11B, a Y-axis acceleration line sensor 106 is provided on the inner wall surface P4 of the main body (housing) 100, and a Z-axis acceleration line sensor is provided on the inner wall surface P1 of the main body (housing) 100. 108 is provided. FIG. 11B shows a state in which the main body (housing) 100 does not rotate about the X axis. FIG. 11C shows components for each coordinate axis of the vector G1 corresponding to FIG. Here, it is assumed that the main body (housing) 100 of the input device 101 is rotated by θ2 about the X axis.

FIG. 11D shows a state in which the rotation (rotation angle θ2) about the X axis of the main body (housing) 100 has occurred. FIG. 11E shows components for each coordinate axis of the vector G1 corresponding to FIG. In FIG. 11E, the vector G1 can be decomposed into a Z-axis component and a Y-axis component (both indicated by thick dotted lines in the figure). That is, the Z-axis component of gravity acceleration G (that is, Z-axis acceleration γ _z ) is G1 cos θ2, and similarly, the Y-axis component of gravity acceleration (vertically upward) G (that is, Y-axis acceleration γ _y ) is G1sin θ2. As is clear, the Y-axis acceleration γ _y and the Z-axis acceleration γ _z include information on the rotation angle θ2 around the X axis. Therefore, by detecting the Z-axis acceleration γ _z and the Y-axis acceleration γ _y , the calculations of the above expressions (4) and (5) can be executed. That is, the equations (4) and (5) can be modified as the following equations (6) and (7). G1 is the following (
8) can be expressed as:

Substituting Eq. (8) into the denominator of Eqs. (6) and (7), and placing γ _y = G1sin θ2, γ _z = G1 cos θ2 in Eqs. (6) and (7), Equations (1) and (2) can be obtained. That is, the coordinate conversion processing unit 532 executes the calculations of the equations (1) and (2), thereby converting the Y-axis angular velocity ω _y and the Z-axis angular velocity ω _z into the U-axis angular velocities ω _u and ω _v , respectively. Each can be converted.

  FIG. 12 is a diagram illustrating the mutual relationship between ωy, ωz, ωu, ωv, γy, and γz. As described above, each of the Y-axis angular velocity ωy and the Z-axis angular velocity ωz is detected by the Y-axis gyro sensor 102 and the Z-axis gyro sensor 104. Each of the Y-axis acceleration γy and the Z-axis acceleration γz is detected by the Y-axis acceleration sensor 106 and the Z-axis acceleration sensor 108. The U-axis angular velocity ωu and the V-axis angular velocity ωv are obtained by the coordinate conversion described above.

(Countermeasure when the point direction is in the vicinity of the vertically upward direction or in the vicinity of the vertically downward direction) When the main body (housing) 100 of the input device 101 is vertically upward or vertically downward, the vertical axis (G axis) and the Q plane The angle θ1 formed by (see FIG. 4A) is approximately 90 °. Therefore, the V-axis component G1 (= Gcos θ1), which is the vertical axis in the Q plane perpendicular to the X-axis, of the gravitational acceleration (vertically upward) G is approximately 0 because cos90 = 0. Therefore, the Y-axis acceleration (γ _y = G1sin θ2) and the Z-axis acceleration (γ _z = G1 cos θ2) are also substantially zero. Therefore, the denominator in the above equations (1) and (2) is substantially 0, and the calculation for coordinate conversion becomes impossible.

  Actually, the pointing direction (point direction) of the main body (housing) faces the screen or the screen and is considered to be no problem because it is in a substantially horizontal state, but as a rare case, the input device 101 As long as the pointing direction of the main body (housing) 100 is in the vicinity of vertically upward or in the vicinity of vertically downward, it is desirable to take some measures.

  Therefore, for example, when the pointing direction (point direction) of the front end of the main body (housing) 100 is right above or right below, the signal output from the input device 101 is suppressed to zero (that is, the main body portion The method of prohibiting the output of signals according to movement) is adopted. As a result, the processing load on the data processing device (the side receiving the signal from the input device 101) (the burden associated with the countermeasure processing) is reduced.

  Further, for example, when the indicated direction of the main body (housing) 100 is near vertically upward or near vertically downward, the coordinate conversion processing by the coordinate conversion processing unit 532 is stopped, and the Y-axis angular velocity before the coordinate conversion processing Each of the signal and the Z-axis angular velocity signal may be output as it is. In this case, the data processing device (the side receiving the signal from the input device 101), for example, determines the position of the control target (for example, cursor pointer) on the display unit based on the received Y-axis angular velocity signal and Z-axis angular velocity signal. There is an advantage that it can be controlled.

Note that the indication direction (point direction) at the tip of the main body (housing) 100 is directly above or directly below, for example, the denominator in the above equations (1) and (2) is a predetermined threshold value. Can be detected. That is, when the denominator is smaller than the threshold value, it can be determined that the point direction is close to directly above or directly below.

  FIG. 13 is a flowchart illustrating an example of a processing order of coordinate conversion processing for rotation compensation. The coordinate conversion processing unit 532 provided in the input device 101 takes in the acceleration data γy and γz (step S700) and takes in the angular velocity data ωy and ωz (step S701).

  Next, γyωy−γyωz is set as Su (step S702), γyωy + γzωz is set as Sv (step S703), the denominators of the above equations (1) and (2) are set as k (step S704), and kSu is set. ωu, kSv is set to ωv (step S705). Thereby, the rotational angular velocity ωu about the U axis and the rotational angular velocity ωv about the V axis are obtained.

  Next, the physical quantity / displacement amount conversion unit (coefficient calculation unit) 534 calculates the lateral displacement amount MH by multiplying ωv by the coefficient βyv (step S706), and multiplies ωu by the coefficient βzu to obtain the vertical displacement amount. MV is calculated (step S707), and Mh and Mv are calculated by integer processing (step S708).

  Further, when the point direction of the main body (housing) 100 of the input device 101 is near or directly below, both the lateral displacement amount and the longitudinal displacement amount are zero. Therefore, when Mh = 0 and Mv = 0, the process is terminated without outputting a signal from the input device 101 (step S709), and only when the determination in step S709 is No, the horizontal displacement amount Mh and The vertical displacement amount Mv is transmitted to the data processing device 600 (step S710).

(Second Embodiment)
Each of FIGS. 14 to 16 shows an example of the external configuration of another example (an example in which an enable switch or the like is provided) that detects rotation about the X axis, rotation about the Y axis, and rotation about the Z axis. FIG.

  In FIG. 14, an operation unit 700 having an output enable switch SW <b> 1 (for example, a push-down or slide-type switch) for switching permission / prohibition of signal output is provided in the main body (housing) 100 of the input device 101.

  Here, for example, it is assumed that the input device 101 has a cursor pointer movement control function (first control input function) and a screen scroll function (second control input function). The output enable switch SW1 shown in FIG. 14 is a common output enable switch that controls enable / disable of each function in common. Since the operation of the output enable switch SW1 can be performed regardless of the posture in the space of the main body (housing) 100, it is easy for the user to operate the output enable switch SW1.

  By providing the output enable switch SW1, a signal is output from the input device 101 only when the user operates the operation unit 700 (for example, only when the output enable switch SW1 is pressed). Therefore, in a period during which the operation unit 700 is not operated (for example, a period in which the output enable switch SW1 is not pressed), even if the main body (housing) 100 is moved, for example, the position displacement of the control target (for example, cursor pointer) Etc. does not occur. Therefore, according to the input device 101 of FIG. 14, it is possible to reliably prevent the movement of the control target that is not intended by the user, thereby further improving the usability of the input device.

Various variations are conceivable for the configuration of the operation unit 700. In FIG. 15, output enable switches SW2 and SW3 corresponding to each of the two functions of the input device 101 are provided. In this case, the user can selectively turn on either the cursor movement control function or the screen scroll control function, and the convenience for the user is improved.

  In FIG. 16, the operation unit 700 is provided with a changeover switch SW4. For example, the input device has a cursor pointer movement control function (first control function) and a screen scroll function (second control function), but the user wants to use only the first control function. There is also a possibility. Therefore, FIG. 16 shows a changeover switch (scroll / cursor movement changeover switch) SW4 for switching a function (type of signal processing) so that any one of a plurality of functions of the input device 101 can be selected. It is provided in the operation unit 700 of the main body (housing) 100. Accordingly, the user can select and use one function desired to be used from among a plurality of functions of the input device 101. Therefore, user convenience is further improved.

  FIG. 17 is a diagram illustrating an internal configuration of another example (an example in which an enable switch or the like is provided) that detects rotation around the X axis, rotation around the Y axis, and rotation around the Z axis.

  17 further includes an operation unit 700 (having at least one of the switches SW1 to SW4 shown in FIGS. 14 to 16) and an input interface 702 in addition to the configuration of FIG. ing. The operation unit 700 functions as, for example, a mode switching switch for switching a signal output mode from the input device 101.

  Further, for example, in order to realize a function equivalent to that of a mouse, a button having the same function as the left / right click button of the mouse can be added in addition to the configuration of FIG. In this case, the usability of the input device 101 is further improved.

  As described above, according to at least one embodiment of the present invention, it is possible to realize an input device capable of easily scrolling a screen. Further, for example, it is possible to easily give the input device a function of moving the cursor pointer up, down, left and right and a function of scrolling the screen. Therefore, for example, a pointing device with operability close to that of a multifunctional mouse, operability close to that of a pointer or laser pointer, and easy to use and multifunctional pointing device that can be easily scrolled. Can be realized.

  The input device according to the present embodiment is particularly useful in scenes such as presentations in which a mouse, a support rod, a laser pointer, or the like has been conventionally used, but is not limited thereto. For example, when used as an input device such as a computer, that is, as a user interface, it can be used for input of any application that operates there. In addition, the input device of the present embodiment can be applied to various systems such as a camera swing system by remote control and a robot control system. Further, the input device of the present embodiment can be applied to devices and systems in general that are equipped with application programs capable of inputting information using a mouse scroll wheel or the like. Conventionally, the operation of rotating (twisting or twisting) the main body (housing) around the point direction has not been utilized at all. The input device of this embodiment is a multifunctional input device having a completely new user interface, and further application is expected.

Although the embodiments of the present invention have been described in detail, those skilled in the art will readily understand that many modifications are possible without departing from the novel matters and effects of the present invention. Therefore, all such modifications are included in the present invention. Further, the term input device is to be interpreted in the broadest sense, and broadly includes input devices that can input signals corresponding to spatial displacement. In addition, the configuration of the three-dimensional motion sensor is not limited to the above-described embodiment, and other configurations (for example, a configuration having a magnetic sensor in addition to the gyro sensor and the acceleration sensor) may be adopted. Can do. Further, the spatial displacement includes the posture and rotation of the input device, and also includes translation. Note that the translation (horizontal movement, vertical movement, etc.) of the input device can be calculated by integrating fluctuations in the output of the acceleration sensor with time.

101 input device (for example, a three-dimensional input device such as a pointing device),
100 body (housing) of the input device,
102 Y-axis gyro sensor (Y-axis angular velocity sensor),
104 Z-axis gyro sensor (Z-axis angular velocity sensor),
106 Y-axis acceleration sensor, 108 Z-axis acceleration sensor,
110 X-axis gyro sensor (X-axis angular velocity sensor),
111 motion sensor, 400 screens,
502 3D motion sensor unit, 512-518, 519 amplifier,
520-526, 528 A / D converter, 530 conversion processing unit (for example, CPU),
531 First signal processing unit, 532 Coordinate transformation processing unit, 533 Second signal processing unit,
534 coefficient calculation unit (physical quantity / control quantity conversion unit), 536 wireless transmission unit,
AN1, AN2 antenna, 600 data processing device,
610 receiving unit, 620 data processing unit (CPU, etc.), 630 ROM,
640 RAM, 650 display control unit, 660 display unit, 662 display

Claims (10)

  An input device comprising: a main body portion having a longitudinal axis; and a motion sensor portion for detecting rotation about the longitudinal axis of the main body portion. The input device according to claim 1,
The motion sensor unit is
About the X axis in a three-dimensional first orthogonal coordinate system determined by an X axis coinciding with the longitudinal axis of the main body and a Y axis and a Z axis orthogonal to each other in a first plane perpendicular to the X axis An input device comprising an X-axis gyro sensor that detects the angular velocity of the X-axis. The input device according to claim 1 or 2,
The input device is used to determine a control amount related to a control target;
The input device further includes a physical quantity / control amount conversion unit that converts a physical quantity signal from the motion sensor unit into a control amount signal indicating the control amount. An input device according to claim 2 or claim 3,
The motion sensor unit is
A Y-axis gyro sensor for detecting an angular velocity about the Y-axis;
A Z-axis gyro sensor that detects an angular velocity about the Z-axis, and
A first signal processing unit that performs first signal processing based on an angular velocity signal about the X axis;
A second signal processing unit that executes second signal processing based on the angular velocity signal for the Y axis and the angular velocity signal for the Z axis;
An input device comprising: The input device according to claim 4,
A priority processing determining unit that determines which of the first signal processing and the second signal processing should be prioritized, and a first process that is output from the first signal processing unit based on the determination by the priority processing determining unit An input device, further comprising: a priority selection unit that includes a selection unit that selectively outputs one of the signal and the second processing signal output from the second signal processing unit. The input device according to claim 4 or 5, wherein
The motion sensor unit is
A Y-axis acceleration sensor that detects acceleration about the Y-axis;
A Z-axis acceleration sensor that detects acceleration about the Z-axis, and
The second signal processor is
A coordinate conversion processing unit that performs coordinate conversion based on the Y-axis acceleration detected by the Y-axis acceleration sensor and the Z-axis acceleration detected by the Z-axis acceleration sensor;
The coordinate conversion processing unit is a horizontal axis on a first surface perpendicular to the X axis, each of the Y axis angular velocity detected by the Y axis gyro sensor and the Z axis angular velocity detected by the Z axis gyro sensor. And converting each of the U-axis angular velocity and the V-axis angular velocity in a two-dimensional second orthogonal coordinate system determined by the U-axis and the V-axis that is an axis perpendicular to the U-axis on the first surface. Input device. The input device according to any one of claims 1 to 6,
An input device comprising an operation unit including an output enable switch for switching permission / prohibition of signal output from the input device. The input device according to claim 5,
An operation unit including a changeover switch for forcibly switching between executing the first processing by the first signal processing unit and executing the second signal processing by the second signal processing unit. An input device. The input device according to claim 5,
The first processing signal output from the first signal processing unit is a control amount signal of a scroll amount of a display screen or a zoom magnification of a display image, and the second processing signal output from the second signal processing unit. Is a control amount signal related to the displacement of the cursor pointer on the display screen. An input device according to any one of claims 1 to 9,
A data processing device that receives a transmission signal of the input device and performs given data processing based on the received signal;
A data processing system comprising:

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