JP2007334857A - Operation signal creating apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an operation signal creating apparatus which can install an information input device freely. <P>SOLUTION: An operation signal creating apparatus 1 generates the operation signal which operates an electronic appliance 100, and includes a vibration detection sensor 10 which detects a vibration of a fabric or a work fixed to the fabric, or an article fixed and used; and an operation signal creating section 20 which generates the operation signal when an output signal of a vibration detection sensor judges whether a predetermined conditions are fulfilled and the output signal fulfills the predetermined conditions. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an operation signal generation device.

2. Description of the Related Art An operation signal generation device that has an information input device for a user to input information and generates an operation signal for operating an electronic device based on operation information input to the information input device is known. As an information input device for a user to input operation information to the operation signal generation device, an information input device having a mechanical mechanism such as a push button and an information input device such as a touch panel are known. In addition, a switch that controls on / off of the power supply of an electronic device by a mechanical mechanism is known.
JP 2005-286809 A

  An information input device having a mechanical mechanism such as a push button may deteriorate due to external factors such as dust. Moreover, since there is a possibility of short-circuiting due to moisture, it was difficult to install around water, and it was difficult to install in a fire-prohibited place because there was a risk of sparks during operation. Furthermore, according to the information input device having a mechanical mechanism, the installation surface is uneven, and thus the installation location may be limited from the appearance.

  Note that a touch panel is known as an information input device that does not appear uneven on the surface, but it is difficult to place it around water due to the characteristics of the mechanism, and the installation location is also from the viewpoint of the rigidity of the panel surface. Limited.

  An object of the present invention is to provide an operation signal generation device capable of freely installing an information input device.

(1) An operation signal generation device according to the present invention includes:
An apparatus for generating an operation signal for operating an electronic device,
A vibration detection sensor for detecting vibrations of a building, a workpiece fixed to the building, or an article to be used stationary;
An operation signal generation unit that determines whether an output signal of the vibration detection sensor satisfies a predetermined condition, and generates the operation signal when the output signal satisfies the predetermined condition;
including.

  According to the present invention, the operation signal for operating the electronic device is generated based on the output signal of the vibration detection sensor (vibration detected by the vibration detection sensor). Here, since the vibration detection sensor is configured to detect vibration of a building or the like, it can be said that the operation signal generation device generates an operation signal based on a mode in which the building or the like vibrates. That is, according to the operation signal generation device according to the present invention, the operation signal for operating the electronic device is generated by the user vibrating the building or the like.

  Therefore, according to the present invention, an operation signal generating device excellent in operability that can generate an operation signal by simply giving vibration to a building or the like without operating an operation unit such as a button or a key. Can be provided.

  In addition, according to the operation signal generation device according to the present invention, the user can operate the electronic device without operating the operation unit. Therefore, according to the present invention, it is not necessary to provide the operation unit in a manner that can be perceived by the user. That is, according to the present invention, since it is not necessary to expose the operation unit, it is possible to provide an operation signal generation device that can be arranged on a building or the like without being restricted in appearance.

(2) In this operation signal generator,
You may further have the holding member holding the said vibration detection sensor which comprises the said building, the said workpiece, or the said article | item.

  By installing the vibration detection sensor on a member (holding member) constituting the building or the like, it becomes possible to detect vibration of the building or the like with high accuracy. The vibration detection sensor applicable to the present invention is not limited to a vibration detection sensor having a specific configuration, and any vibration detection sensor that has already been publicly known may be applied. For example, an angular velocity sensor (gyro sensor) or an acceleration sensor may be used as the vibration detection sensor.

(3) In this operation signal generator,
The main surface of the holding member has a vibration input region,
The vibration input area and its peripheral area on the main surface may be flat.

  Here, the vibration input area is the most accurate vibration input by the user to the holding member (for example, the tapping vibration generated in the holding member by hitting the holding member) out of the main surface (the surface facing the user) of the holding member. An area often transmitted to the vibration detection sensor. The vibration input area may be an area overlapping with the vibration detection sensor (operation signal generation device unit).

(4) In this operation signal generator,
A fluorescent paint may be applied to at least a part of the vibration input region.

  According to this, since the user can accurately perceive the vibration input area in a dark place, the electronic device can be operated accurately.

(5) In this operation signal generator,
It further has a light emitting component,
At least a part of the vibration input region may be configured to transmit light emitted from the light emitting component.

  According to this, since the user can accurately perceive the vibration input area in a dark place, the electronic device can be operated accurately.

(6) In this operation signal generator,
Further comprising a substrate on which the vibration detection sensor is mounted;
The substrate may be disposed at a distance from the holding member.

(7) In this operation signal generator,
The substrate may be supported by one or a plurality of points and held by the holding member.

  According to this, since the vibration of the holding member can be accurately transmitted to the vibration detection sensor, a highly accurate operation signal generation device can be provided.

(8) In this operation signal generator,
The substrate may be held by the holding member via a resin member.

  In the present invention, the resin member may be selected according to the operation accuracy required for the operation signal generation device. For example, if a hard resin member is used, the operation signal generation device can be set so as to accurately react to the vibration of the holding member. On the other hand, if a soft resin member is used, the vibration energy of the holding member can be absorbed by the resin member, so that the influence of vibration having a small amplitude (energy) can be ignored. Therefore, an operation signal generation device with few malfunctions can be provided.

(9) In this operation signal generator,
Further comprising a substrate on which the vibration detection sensor is mounted;
The substrate may be in contact with the holding member.

  According to this, since the vibration of the holding member can be accurately transmitted to the vibration detection sensor, a highly accurate operation signal generation device can be provided.

(10) In this operation signal generator,
You may further have a waterproof housing | casing by which the said vibration detection sensor is arrange | positioned at least.

  According to this, since the vibration detection sensor can be prevented from coming into contact with moisture, the vibration detection sensor can be disposed around the water or the like.

(11) In this operation signal generation device,
You may further have an airtight housing | casing by which the said vibration detection sensor is arrange | positioned at least.

  According to this, the vibration detection sensor can be safely installed in a place where fire is strictly prohibited.

(12) In this operation signal generation device,
A determination condition storage unit for storing the predetermined condition;
A determination condition setting unit for storing the predetermined condition in the determination condition storage unit based on an output signal of the vibration detection sensor;
May further be included.

  When different users perform the same operation, vibrations generated thereby may be affected by individual differences among the users. For example, even when the user A and the user B perform the same operation, the amplitude and attenuation pattern of the vibration detected by the vibration detection sensor and the interval between the amplitude peaks may be different.

  The operation signal generation device may be designed to operate by absorbing this individual difference. However, by using the individual difference, it is possible to provide an operation signal generation device to which a security function is added. .

  For example, if a determination condition is set based on an output signal of a vibration detection sensor when a specific user vibrates the vibration detection sensor, it is difficult for another user to accurately reproduce the vibration, and thus a third party It is possible to prevent the electronic device from being operated.

  In addition, according to this, since it is possible to set the determination condition in consideration of the user's own characteristics, it is possible to accurately react to vibrations generated by a specific user, and an operation signal generation device with few malfunctions. Can be provided.

(13) In this operation signal generator,
The operation signal generator is
Based on the output signal of the vibration detection sensor, a hit number detection unit that detects the number of times the user has hit the building, the workpiece, or the article,
A correspondence storage unit that stores a correspondence between the number of times of hitting and the operation signal;
Further including
Based on the correspondence, an operation signal corresponding to the number of hits detected by the hit number detecting unit may be generated.

  According to this, the user can cause the electronic device to perform a desired operation by a simple operation of “striking a building or the like”.

(14) In this operation signal generator,
It may further include a correspondence setting unit that sets a correspondence between the hit count and the operation signal and stores the correspondence in the correspondence storage unit.

  According to this, it is possible to provide an operation signal generation device that most closely matches the usage mode of the user.

(15) In this operation signal generator,
The correspondence storage unit
Storing the correspondence between the number of hits and the operation signal for each processing system;
A processing system switching unit further selecting and switching one of the processing systems from a plurality of processing systems;
The operation signal generator is
An operation signal associated with the detected number of hits may be generated based on the correspondence relationship in the selected processing system.

  According to this, since it is possible to cause the electronic device to perform various operations, it is possible to provide an operation signal generation device with excellent operability.

(16) In this operation signal generator,
The electronic apparatus may further include setting means for setting the operation of the electronic device based on an output signal of the vibration detection sensor to be valid or invalid.

  According to this, it becomes possible to prevent malfunction of the electronic device.

  The setting means referred to here may be, for example, a contact detection unit that senses a user's contact. Then, the operation signal generation device may be set to validate the operation of the electronic device based on the output signal of the vibration detection sensor only when the user is in contact with the contact detection unit. The contact detection unit can use any known device such as an electrostatic sensor, a pressure sensor, or a temperature sensor.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The embodiments described below do not unduly limit the contents of the present invention described in the claims. Also, not all of the configurations described below are essential constituent requirements of the present invention.

  FIGS. 1-13 is a figure for demonstrating the operation signal production | generation apparatus 1 which concerns on embodiment to which this invention is applied. Note that the operation signal generation device 1 is a vibration of a building, a workpiece fixed to the building, or an article that is used while standing (referred to as “building etc.” as appropriate). Is a device that generates an operation signal for operating (operating) the electronic device based on the above.

  Here, “buildings” include houses (walls, floors, ceilings, roofs, pillars), buildings and roads, harbor facilities and dams, water and sewage systems, pipelines, ships, trains, and automobiles. “Workpieces fixed to buildings” include doors, bathtubs, bath units, ventilation fan units, toilet units, system kitchens, power poles installed on roads, power transmission towers, and manholes. . In addition, the “articles that are used while standing” include a table, a chair, furniture such as a bookshelf and a closet, an electronic device main body that is an operation target provided in a house, and the like, and a remote controller. However, these are examples of buildings, workpieces, and articles, and the present invention is not limited thereto. The present invention also covers members belonging to different classifications such as a building and a workpiece, a workpiece and a stationary article, and a stationary article and a building.

  Also, the electronic device that is an operation target of the present invention is not particularly limited. For example, the electronic device may be a lighting device, an AV device, an air conditioner, a navigation system, a door (automatic door), an electronic key, a ventilation fan, or a solenoid valve. However, the electronic devices listed here are examples of the subject of the present invention, and the present invention is not limited to these.

  As shown in FIG. 1, the operation signal generation device 1 according to the present embodiment includes a vibration detection sensor 10 that detects vibration. In the present embodiment, an operation signal for operating the electronic device is generated by the operation signal generation unit 20 described later based on the output signal of the vibration detection sensor 10. Therefore, in the present embodiment, the vibration detection sensor 10 may be regarded as an operation information input device (user interface) for inputting operation information to the operation signal generation device 1.

  As the vibration detection sensor 10, any sensor capable of detecting vibration of an object (such as a building) can be used. For example, an angular velocity sensor (gyro sensor) may be used as the vibration detection sensor 10. Here, the angular velocity sensor is a sensor that measures a rotational speed (rotational angular velocity) with respect to a rotational motion around a certain rotational axis, and is configured to output an analog voltage value corresponding to the rotational angular velocity. It may be. The gyro sensor may be a vibrating gyroscope that vibrates using a piezoelectric effect, for example. In this type of sensor, at least a part of the gyro element is vibrated by applying an AC voltage to the gyro element (vibrating body such as crystal), and the current (voltage) according to the rotation rate and angular velocity is obtained using the Coriolis force. Is generated. By amplifying this current (voltage) signal internally and outputting a voltage proportional to the angular velocity, it becomes possible to output an electrical signal corresponding to the vibration. In addition, the kind of gyroscope is arbitrary, For example, the gyrosensor which applied the MEMS (micro electro mechanical system) technique may be used. The vibration detection sensor 10 may be configured to detect vibration only in a predetermined one-axis direction, or may be configured to detect two or three axes orthogonal to each other.

  However, the vibration detection sensor 10 applicable to the present invention is not limited to the gyro sensor. For example, an acceleration sensor that detects acceleration may be used as the vibration detection sensor 10. This can also detect vibrations of buildings and the like.

  The operation signal generation device 1 according to the present embodiment includes an analog processing circuit (analog front end circuit) 15 as shown in FIG. The analog processing circuit 15 includes a low-pass filter / op-amp 14 and an A / D converter 16, and may be configured to accept an input of the analog signal 12 output from the vibration detection sensor 10 and generate a corresponding digital signal 18. Good. In the present embodiment, the analog processing circuit 15 may be regarded as a part of the vibration detection sensor 10 or an operation signal generation unit 20 described later. However, the operation signal generating apparatus 1 according to the present embodiment may be configured not to include the analog processing circuit 15.

  As shown in FIG. 1, the operation signal generation device 1 according to the present embodiment includes an operation signal generation unit 20 that generates an operation signal for operating an electronic device. The operation signal generated by the operation signal generation unit 20 is a signal for causing the electronic device to perform a specific operation. For example, even if it is a signal (ON / OFF inversion signal) for controlling on / off of the electronic device. Alternatively, it may be a command signal (operation selection signal).

  The operation signal generation unit 20 generates an operation signal based on the output signal of the vibration detection sensor 10. In the present embodiment, the operation signal generation unit 20 determines whether the output signal of the vibration detection sensor 10 satisfies a predetermined condition, and when the output signal satisfies the predetermined condition, the operation signal Is configured to generate That is, it can be said that the operation signal generation unit 20 is configured to generate an operation signal only when a specific vibration is applied to a building or the like.

  In the present embodiment, the operation signal generation unit 20 (operation signal generation device 1) includes a hit count detection unit 30, as shown in FIG. The hit number detection unit 30 detects the number of times the user has hit a building or the like based on the output signal of the vibration detection sensor 10. The hit number detection unit 30 receives an output signal of the vibration detection sensor 10 (for example, the digital signal 18 output from the analog processing circuit 15), and determines the number of hits based on the transition of the output signal. It can be realized by a microcomputer including a CPU.

  The method for detecting the number of hits by the hit count detection unit 30 is not particularly limited. Hereinafter, taking as an example the case where a gyro sensor is used as the vibration detection sensor 10, an example of a procedure in which the hit count detection unit 30 detects the hit count will be described.

  FIG. 2A is a diagram illustrating an output signal of the vibration detection sensor 10 when the vibration detection sensor 10 (building or the like) vibrates once. That is, when the vibration detection sensor 10 (a building or the like) vibrates once, the vibration detection sensor 10 outputs an analog signal (analog voltage signal) shown in FIG. 2A is a voltage value output when the vibration detection sensor 10 rotates to the right, and the voltage value 222 is a voltage output when the vibration detection sensor 10 rotates to the left. Value. The vibration detection sensor 10 is displaced to the same extent on both sides of a predetermined reference axis every time a building or the like vibrates. Therefore, when the building or the like vibrates once, the vibration detection sensor 10 outputs a signal having two peaks that are symmetrical with respect to the reference voltage, as shown in FIG.

  When this is processed by the analog processing circuit 15, a digital signal shown in FIG. 2B is generated. That is, FIG. 2B shows the result of digital conversion of the analog voltage value output from the vibration detection sensor 10. Assuming that the voltage value of the resting state is 0, the section 220 ′ having a positive value rotates right (generation of a right rotation pulse), and the section having a negative value rotates left (left rotation pulse). Occurrence). When a building or the like is hit once, a right rotation and a left rotation are detected as a pair. Therefore, it is possible to detect a single hit by detecting the pair of right rotation pulse and left rotation pulse.

  Next, a method in which the hit count detection unit 30 determines the hit count will be described. FIG. 3 is a diagram illustrating an example of an output signal output from the vibration detection sensor 10 when the vibration detection sensor 10 (a building or the like) is hit twice. In FIG. 3, the output signal 250 is indicated by a continuous line (analog value), but the output signal 250 may be expressed by a set of discrete points (digital value).

  Referring to FIG. 3, an output signal 250 indicating the output of the vibration detection sensor 10 is obtained after regular pulses having extreme values (maximum value or minimum value) of P1, P2, P3, and P4, and then P5, P6, and P6. A derivative pulse with extreme values of P7 and P8 appears. Here, the pulses having the extreme values of P1 and P2 are generated by the first hit operation, and the pulses having the extreme values of P3 and P4 are generated by the second hit operation. The subsequent irregular pulses (pulses having extremal values P5, P6, P7, and P8) are generated by the shaking generated as a reaction of the first and second tapping operations.

  In the present embodiment, the threshold value (+ S, −S) of the intensity (voltage value) of the output signal 250 is set, and when a pair of pulses exceeding the threshold value is detected, it is determined that one hit operation has been performed. Also good. When this is done, the output signal 250 shown in FIG. 3 has two pulses exceeding the threshold (a pair of pulses having P1 and P2 as extreme values, and P3 and P4 having extreme values 1 within a predetermined period. Therefore, it can be determined that there has been a tapping operation twice. That is, the hit number detection unit 30 may be configured to detect the number of hit operations by counting the number of pulses that appear within a predetermined period.

  In the present embodiment, an extreme value range (+ l, -l) that defines both the upper and lower limits that the intensity (voltage value) of the output signal 250 can take is set, and the extreme value is within the extreme value range. When a pair of pulses is detected, it may be determined that one hit operation has been performed. In this way, the output signal 250 has two pairs of pulses whose extreme values are within the extreme value range (one pair of pulses having P1 and P2 as extreme values, and one pair of pulses having P3 and P4 as extreme values). Therefore, it can be determined that there has been a tapping operation twice. Also, according to this, when the vibration detection sensor 10 outputs a signal having a value exceeding the extreme value range, it is possible to prevent the electronic device from operating based on the vibration. Therefore, malfunction of the electronic device can be prevented.

  In the present embodiment, the operation signal generation device 1 may be configured to be able to set the determination condition (threshold value or extreme value range) for the hitting operation. For example, as shown in FIG. 1, the operation signal generation device 1 may include a determination condition storage unit 32 and a determination condition setting unit 34 that are configured to be rewritable. The number of hits may be detected based on the determination condition stored in the unit 32. Note that the determination condition stored in the determination condition storage unit 32 may be set based on the output signal of the vibration detection sensor 10. Specifically, a determination condition setting period is provided to allow the user to perform a hitting operation, and based on a signal output from the vibration detection sensor 10, a determination condition such as a threshold value or an extreme value range (the above-described S value or l Value) may be set and stored in the determination condition storage unit 32. At this time, the appearance interval (cycle) of the pulses may also be detected and stored in the determination condition storage unit 32.

  In general, the action (strength and speed) of hitting an object varies from user to user. FIG. 4A shows an output signal 270 of the vibration detection sensor 10 when the user A performs the hitting operation twice in succession, and FIG. The output signal 280 of the vibration detection sensor 10 when performed once is shown. As shown in FIGS. 4A and 4B, even when the same operation of “tapping twice” is performed, the intensity and period of the output signal are different for each user. Therefore, by setting a determination condition according to a specific user, it is possible to prevent a third party from operating the electronic device, and it is possible to add a security function to the operation signal generation device 1. Note that the output signal of the vibration detection sensor 10 also varies depending on a hitting area (operation information input area) of a building or the like. Therefore, if the user freely sets a hit area within a certain range and sets the determination condition based on the output signal of the vibration detection sensor 10 when the user hits the hit area, the hit area determined by the user is set. If it is not hit, it becomes difficult to generate a vibration that satisfies the determination condition. Therefore, it is difficult for a third party to reproduce the vibration that satisfies the determination condition, and it becomes possible to realize a highly reliable security system. Further, by setting the determination information for each user, it is possible to prevent malfunction of the operation signal generation device 1, so that the operation signal generation device 1 can be operated with high accuracy.

  The operation signal generation device 1 according to the present embodiment includes a correspondence relationship storage unit 40 as shown in FIG. The correspondence storage unit 40 stores the correspondence between the number of times of hitting (vibration pattern) and the operation signal. That is, the correspondence relationship storage unit 40 may store the correspondence relationship between the output signal of the vibration detection sensor 10 and the operation signal. Note that the correspondence relationship storage unit 40 may be configured by a rewritable memory such as a flash memory or an EEPROM so that reference data can be set in the rewritable memory based on an external input. Alternatively, the correspondence relationship may be incorporated into the instruction code of the program and executed by the CPU so as to function as the correspondence relationship storage unit 40.

  The operation signal generation device 1 according to the present embodiment includes an operation signal generation processing unit 25. The operation signal generation processing unit 25, based on the data indicating the correspondence stored in the correspondence storage 40, the number of hits detected by the hit number detection unit 30 (that is, the vibration pattern detected by the vibration detection sensor 10). An operation signal (command) corresponding to is generated. As a result, it is possible to generate a desired operation signal by combining a simple operation of “striking”, and thus it is possible to provide the operation signal generation device 1 having excellent operability.

  The correspondence relationship storage unit 40 may store the correspondence relationship between the output signal of the vibration detection sensor 10 and the operation signal, such as the number of hits and the vibration pattern, for each processing system. In this case, the operation signal generation device 1 includes a processing system switching unit for switching and executing a plurality of processing systems. And the operation signal generation part 20 may be comprised so that the operation signal matched with the detected number of times of tapping (or vibration pattern) based on the correspondence in the selected processing system may be comprised.

  The operation signal generation device 1 according to the present embodiment includes a correspondence setting unit 42 as shown in FIG. The correspondence setting unit 42 sets the correspondence between the output signal (the number of hits and the vibration pattern) of the vibration detection sensor 10 and the command and stores it in the correspondence storage 40. For example, a microcomputer including a CPU or a CPU Etc. can be realized.

  The operation signal generation device 1 according to the present embodiment may include a contact detection unit (not shown). The contact detection unit may be realized by an electronic device that can detect that the user is in contact, such as an electrostatic sensor (touch panel), a temperature sensor, or a pressure sensor. And the operation signal generator 1 which concerns on this Embodiment may be comprised so that operation of an electronic device is enabled only during the period when the user is contacting the contact detection part. Accordingly, it is possible to prevent the electronic device from malfunctioning when the user does not intend to operate the electronic device using the operation signal generation device 1. The contact detection unit can be regarded as a means for setting the operation of the electronic device based on the output signal of the vibration detection sensor 10 to be valid or invalid. That is, the operation signal generation device 1 according to the present embodiment may be regarded as including a setting unit that sets the operation of the electronic device based on the output signal of the vibration detection sensor 10 to be valid or invalid. However, the setting means applicable to the present invention is not limited to the contact detection device.

  The operation signal generation device 1 according to the present embodiment may be configured to transmit the operation signal generated by the operation signal generation unit 20 to the electronic device 100 in a wired or wireless manner. The electronic device 100 receives the operation signal and performs a predetermined operation based on the operation signal. The electronic device 100 may include a control unit 102, and the control unit 102 may cause the electronic device 100 to perform a predetermined operation based on the operation signal. The control unit 102 may be a device that executes a command based on an operation signal, and may be realized by a CPU or a microcomputer including a CPU, for example.

  Each function of the operation signal generation device 1 according to the present embodiment may be realized by a semiconductor integrated circuit device (IC). For example, the operation signal generation unit 20, the hit count detection unit 30, the correspondence relationship storage unit 40, and the correspondence relationship setting unit 42 described above may be realized by a semiconductor integrated circuit device. Moreover, the vibration detection sensor 10 may be configured as a MEMS including a vibration detection element and a control circuit that controls the operation thereof. The analog processing circuit 15 may be mounted on a semiconductor integrated circuit device for realizing the operation signal generation device 1 according to the present embodiment, or may be realized as another semiconductor integrated circuit device or an electronic component. Good.

  As shown in FIG. 5A, the operation signal generation device 1 according to the present embodiment includes a substrate 50 on which at least the vibration detection sensor 10 is mounted. A semiconductor integrated circuit device for realizing the function of the operation signal generation unit 20 may be mounted on the substrate 50. Further, the substrate 50 may be mounted with a power supply device or a transmission device for transmitting an operation signal to the outside (electronic device 100). The material and structure of the substrate 50 are not particularly limited. The substrate 50 may have a wiring pattern, and the operation signal generation device 1 may be configured to exchange various signals via the wiring pattern.

  As shown in FIG. 5B, the operation signal generation device 1 according to the present embodiment further includes a housing 52 in which at least the vibration detection sensor 10 is disposed. The substrate 50 may constitute a part of the housing 52. At this time, by using the inner surface of the housing 52 as the circuit surface of the substrate 50, the circuit surface (mounting surface) of the substrate 50 and the integrated circuit device (IC) can be disposed inside the housing 52. The housing 52 may be a waterproof housing. According to this, since it is possible to prevent the circuit surface of the substrate 50 and the integrated circuit device from coming into contact with moisture, it is possible to provide an operation signal generation device that can be safely used around water or outdoors. . Further, the casing 52 may be an airtight casing. Accordingly, it is possible to provide an operation signal generation device that can be used safely in an environment where fire is strictly prohibited. In the present embodiment, the casing 52 (the casing 52 and the electronic component sealed inside the casing 52) may be referred to as the operation signal generation device unit 2.

  FIGS. 6A and 6B are diagrams illustrating a state in which the operation signal generation device unit 2 is provided on the holding member 60. The holding member 60 is a member constituting a building or the like. The holding member 60 may be, for example, a wall material or floor material of a house. The holding member 60 includes a main surface 62 facing the user side. The main surface 62 includes a vibration input area 64 and a peripheral area 66 surrounding the vibration input area 64. The vibration input area 64 is an area where the operation signal generating device unit 2 is attached to the back surface 63 thereof as shown in FIG. 6B. In other words, the vibration input area 64 is an area of the main surface 62 that is closest to the operation signal generation device unit 2 (vibration detection sensor 10), and can transmit the hit vibration to the operation signal generation device unit 2 most efficiently. It can be said that this is an area that can

  In the present embodiment, as shown in FIG. 6B, the operation signal generation device unit 2 may be supported by a support member 68. The support member 68 (holding member 60) may support the operation signal generation device unit 2 at one point or a plurality of points. According to this, since the vibration of the holding member 60 (vibration input region 64) is efficiently transmitted to the operation signal generation device unit 2 (vibration detection sensor 10), a highly accurate operation signal generation device can be provided. However, the operation signal generation device unit 2 (substrate 50) may be held by the holding member 60 with a resin material. Note that the vibration of the holding member 60 can be accurately transmitted to the operation signal generating device unit 2 by attaching the operation signal generating device unit 2 to the holding member via a hard resin material. However, the operation signal generation device unit 2 (substrate 50) may be held by the holding member 60 so as to be in contact with the holding member 60. Alternatively, the vibration detection sensor 10 may be brought into contact with the holding member 60.

  As shown in FIG. 6B, in the holding member 60, the vibration input region 64 and the peripheral region 66 may be configured to be flat. According to the operation signal generation device 1 according to the present embodiment, since the operation signal is generated by vibrating the vibration detection sensor 10, an interface such as a switch or a touch panel operated by the user is not necessary. Moreover, since the electronic device can be operated if vibration can be transmitted to the vibration detection sensor 10, the electronic device is operated even when the user does not accurately grasp the position of the operation unit (vibration input region 64). It becomes possible. For this reason, it is not necessary for the user to accurately recognize the position of the vibration input area 64, and the user can perceive a difference between the vibration input area 64 and the peripheral area 66 such as a concave portion, a convex portion, or a pattern difference. Therefore, the operation signal generation device unit 2 can be installed without being restricted in appearance. In particular, since the main surface 62 can be installed without providing a convex portion, it can be safely installed under the floor or on a road. The vibration input region 64 may be made of the same material as that of the peripheral region 66, but may be made of a different material. The vibration input area 64 may have any configuration capable of detecting a user's contact.

  However, a light emitting paint may be applied to the vibration input region 64. According to this, it becomes possible to make the user recognize the vibration input area 64 in the dark place, and it becomes possible to operate the electronic apparatus accurately even in the dark place.

  Alternatively, a component that emits light may be mounted on the substrate 50 (housing 52), and at least a part of the vibration input region 64 of the holding member 60 is configured to transmit light emitted from the light emitting component. May be. This also allows the user to recognize the vibration input area 64 in a dark place.

  The region 65 to which the operation signal generation device unit 2 is attached in the holding member 60 may be configured integrally with the surrounding region 67. According to this, even when the user strikes a wide unspecified area of the holding member 60, it is possible to transmit vibration to the operation signal generation device unit 2 (vibration detection sensor 10). However, the region 65 to which the operation signal generating device unit 2 is attached in the holding member 60 may be separated from the surrounding region 67, and both are fixed by a member that absorbs vibration (for example, a soft resin member). May be. According to this, it is possible to prevent the vibration applied to the surrounding area 67 from being transmitted to the area 65 (operation signal generating device unit 2). Therefore, it is possible to provide an operation signal generator that is unlikely to malfunction.

  Next, specific operations of the operation signal generation device 1 and the electronic device 100 according to the present embodiment will be described with reference to the correspondence relationship between the number of hits and the operation signal.

  FIG. 7 shows a correspondence table 300 showing the correspondence between the number of hits and the operation signal when the operation signal generation device 1 is configured as a controller of an AV device (TV with a built-in DVD). The correspondence table 300 stores the number of hits and operation signal specifying information for specifying an operation signal corresponding to the number of hits. Note that the correspondence table 300 illustrated in FIG. 7 is a correspondence table when the operation signal generation device 1 has a plurality of processing systems. The operation signal generation device 1 in this case may include a register that stores information indicating the selected processing system. Then, based on the information stored in the register, a correspondence table of a specific processing system is selected, and an operation signal is generated.

  For example, when the main power is off, “1” is stored in the register, and an operation signal for turning on the main power is assigned to the number of times of hitting three times. When the main power is turned on, “2” is stored in the register, and an operation signal for selecting a TV and an operation signal for selecting a DVD are assigned to the number of hits once and twice, respectively. When TV is selected, “3” is stored in the register, and the channel up operation signal, the channel down operation signal, the audio up operation signal, and the audio down operation are respectively obtained for the number of hits 1 to 4 times. A signal is assigned. When the DVD is selected, “4” is stored in the register, and the start / stop inversion operation signal, the recording start signal, the sound up operation signal, the sound are recorded for the number of hits 1 to 4, respectively. A down operation signal is assigned.

  As described above, when the operation signal generation device 1 has a plurality of processing systems, the operability of the electronic device can be improved by selecting the processing systems.

  However, the operation signal generation device 1 may be configured as a device that more simply detects a tapping vibration and outputs an on / off inversion signal. For example, when the electronic device is configured as a lighting device, for example, when the vibration detection sensor 10 detects a tapping vibration when the lighting device is turned off, the operation signal generation device 1 generates a lighting operation signal. It may be configured to. On the other hand, when a hitting vibration is input to the vibration detection sensor 10 while the lighting device is turned on, the operation signal generation device 1 may be configured to generate a turn-off operation signal.

  Alternatively, the operation signal generation device 1 transmits an operation signal to the lighting device every time a vibration is input to the vibration detection sensor 10, and the lighting device receives the operation signal, as shown in FIG. A first dimming state (lighting: high light amount) 310, a second dimming state (medium light amount) 320, a third dimming state (low light amount) 330, and a fourth dimming state (light-off state) 340 are set in this order. It may be configured as follows.

  Alternatively, the lighting device as the electronic device 100 may be configured to be turned on every time an operation signal is received, and to be turned off when a predetermined time has elapsed.

  Next, each process performed by the operation signal generation device 1 according to the present embodiment will be described with reference to a flowchart.

  FIG. 9 is a flowchart for explaining the flow of processing for determining the number of hits using the rotational angular velocity.

  First, the rotational angular velocity is detected by the gyro sensor (vibration detection sensor 10) (step S10).

  Next, the analog voltage value output from the gyro sensor is converted into a digital signal (step S20).

  Next, the rotational angular velocity value (digital signal) is input and held in the work buffer (step S30).

  Next, the number of hits is detected based on the transition of the rotational angular velocity value for the past x seconds held in the work buffer (captured data holding unit) (step S40).

  Next, an operation signal associated with the detected number of hits is generated based on the correspondence between the number of hits and the operation signal (step S50).

  FIG. 10 is a flowchart for explaining the flow of processing for registering the correspondence between the number of times of tapping and the operation signal.

  When a correspondence setting input is received (step S110), a correspondence relationship between the number of hits and a command (operation signal) is set based on the input and stored in the correspondence storage unit (step S120).

  Here, for the input of the correspondence relationship, for example, when detecting that the user has selected “Registration of correspondence relationship”, a screen for selecting “number of times of hitting” and “corresponding command” is displayed, and the user selection process is performed. Prompt and accept the user's selection process.

  The relationship between the “number of times of hitting” and the command to be executed can be set / changed at any time.

  FIG. 11 is a flowchart for explaining processing for registering a determination condition in the determination condition storage unit.

  First, it is determined whether or not it is the determination condition registration period. If it is within the determination condition registration period, the following processing is performed (step S210). The determination as to whether or not the determination condition is registered may be made based on whether or not the contact detection unit detects contact. For example, it is good also as a structure which permits registration of determination conditions, only when the contact detection part has detected the user's contact.

  Based on the signal (rotational angular velocity value) received within the hit determination condition registration period, a determination condition is generated and stored in the determination condition storage unit (step S220).

  FIG. 12 is a flowchart for explaining the flow of processing for determining the number of times of hitting.

  First, a rotational angular velocity is detected by a gyro sensor (vibration detection sensor) (step S310).

  Next, the analog voltage value output from the gyro sensor is converted into a digital signal (step S320).

  Next, the rotational angular velocity value (digital signal) is input and held in the work buffer (step S330).

  The number of hits is detected based on the transition of the rotational angular velocity value for the past x seconds held in the work buffer and the determination condition (step S340).

  Based on the correspondence stored in the correspondence storage unit, an operation signal associated with the number of hits in the selected processing system is generated (step S350).

  FIG. 13 is a flowchart for explaining the operation of the operation signal generation device.

  First, the vibration detection sensor 10 detects vibration and outputs a signal corresponding to the vibration (step S410).

  Next, it is determined whether or not the output signal of the vibration detection sensor 10 satisfies a predetermined condition (step S420). Here, you may determine whether the vibration of the vibration detection sensor 10 is a tapping vibration.

  When the output signal of the vibration detection sensor 10 satisfies a predetermined condition (Yes in step S410), an operation signal is generated based on the signal (step S430). For example, the number of hits may be detected and an operation signal corresponding to the number of hits may be generated.

  The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, the present invention includes substantially the same configuration as the configuration described in the embodiment (for example, a configuration having the same function, method, and result, or a configuration having the same purpose and effect). In addition, the invention includes a configuration in which a non-essential part of the configuration described in the embodiment is replaced. In addition, the present invention includes a configuration that exhibits the same operational effects as the configuration described in the embodiment or a configuration that can achieve the same object. Further, the invention includes a configuration in which a known technique is added to the configuration described in the embodiment.

  For example, the operation signal generation unit 20 may include a feature extraction unit that extracts a vibration feature (vibration pattern) instead of the hit number detection unit 30 or in combination with the hit number detection unit 30. Then, the operation signal generation device detects the characteristics of the vibration detection sensor 10 (building or the like) based on the extracted characteristics of the output signal of the vibration detection sensor 10 and data indicating the correspondence between the characteristics of the output signal and the operation signal. You may be comprised so that the operation signal corresponding to a vibration pattern may be produced | generated.

  Even in this case, the operation signal can be generated with high accuracy based on the vibration applied to the building or the like.

  Alternatively, the operation signal generation unit 20 may be configured to generate a trigger signal as the operation signal when the output signal of the vibration detection sensor 10 satisfies a predetermined determination condition. At this time, the control unit 102 of the electronic device 100 may be configured to generate a control signal for controlling the operation of the electronic device 100 based on the trigger signal. For example, the control unit 102 may receive a trigger signal and perform inversion control that inverts on / off of the electronic device 100. Alternatively, the control unit 102 may be configured to receive a trigger signal and sequentially set (change) the operation mode of the electronic device.

  Alternatively, the operation signal generation unit 20 may be configured to generate a signal indicating the number of hits determined by the hit number detection unit 30 as the operation signal. And the electronic device 100 (control part 102) may be comprised so that the signal which shows the frequency | count of a hit may be received, and the control signal corresponding to the frequency | count of a hit may be produced | generated. At this time, the hit count storage unit may constitute a part of the control unit 102.

The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The figure for demonstrating an operation signal generator. The flowchart for demonstrating the process which determines the frequency | count of a hit. The flowchart for demonstrating the process which registers the correspondence of the frequency | count of a hit and an operation signal. The flowchart for demonstrating the process which registers determination conditions. The flowchart for demonstrating the process which determines the frequency | count of a hit. The flowchart for demonstrating operation | movement of the operation signal production | generation apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Operation signal generator, 2 ... Operation signal generator unit, 10 ... Vibration detection sensor, 12 ... Analog signal, 14 ... Low-pass filter / op amp 15 ... Analog processing circuit, 16 ... A / D converter, 18 ... Digital signal, DESCRIPTION OF SYMBOLS 20 ... Operation signal production | generation part, 25 ... Operation signal production | generation process part, 30 ... Count detection part, 32 ... Judgment condition memory | storage part, 34 ... Judgment condition setting part, 40 ... Correspondence relation storage part, 42 ... Correspondence relation setting part, 50 DESCRIPTION OF SYMBOLS ... Board | substrate 52 ... Housing | casing 60 ... Holding member 62 ... Main surface 63 ... Back surface 64 ... Vibration input area | region 65 ... Area | region 66 ... Area | region 67 ... Area | region 68 ... Support member 100 ... Electronic device 102: Control unit, 220: Voltage value, 222: Voltage value, 250 ... Output signal, 270 ... Output signal, 280 ... Output signal, 300 ... Corresponding table Bull

Claims (16)

An operation signal generation device that generates an operation signal for operating an electronic device,
A vibration detection sensor for detecting vibrations of a building, a workpiece fixed to the building, or an article to be used stationary;
An operation signal generation unit that determines whether an output signal of the vibration detection sensor satisfies a predetermined condition, and generates the operation signal when the output signal satisfies the predetermined condition;
An operation signal generating device including The operation signal generation device according to claim 1,
An operation signal generation device further comprising a holding member that holds the vibration detection sensor, which constitutes the building, the workpiece, or the article. The operation signal generation device according to claim 2,
The main surface of the holding member has a vibration input region,
The vibration signal input region and the peripheral region on the main surface are operation signal generation devices configured to be flat. In the operation signal generating device according to claim 2 or 3,
An operation signal generating device in which a fluorescent paint is applied to at least a part of the vibration input region. In the operation signal generating device according to claim 2 or 3,
It further has a light emitting component,
At least a part of the vibration input region is an operation signal generation device configured to transmit light emitted from the light emitting component. In the operation signal generation device according to any one of claims 1 to 5,
Further comprising a substrate on which the vibration detection sensor is mounted;
The operation signal generating device, wherein the substrate is disposed at a distance from the holding member. The operation signal generation device according to claim 6,
The operation signal generating device is supported by the holding member and supported by one or a plurality of points. The operation signal generation device according to claim 6,
The operation signal generating device, wherein the substrate is held by the holding member via a resin member. In the operation signal generation device according to any one of claims 1 to 5,
Further comprising a substrate on which the vibration detection sensor is mounted;
The operation signal generating device, wherein the substrate is in contact with the holding member. In the operation signal generation device according to any one of claims 1 to 9,
An operation signal generation device further comprising a waterproof housing in which at least the vibration detection sensor is disposed. In the operation signal generation device according to any one of claims 1 to 9,
An operation signal generation device further comprising an airtight housing in which at least the vibration detection sensor is disposed. The operation signal generation device according to any one of claims 1 to 11,
A determination condition storage unit for storing the predetermined condition;
A determination condition setting unit for storing the predetermined condition in the determination condition storage unit based on an output signal of the vibration detection sensor;
An operation signal generator further comprising: The operation signal generation device according to any one of claims 1 to 12,
The operation signal generator is
Based on the output signal of the vibration detection sensor, a hit number detection unit that detects the number of times the user has hit the building, the workpiece, or the article,
A correspondence storage unit that stores a correspondence between the number of times of hitting and the operation signal;
Further including
An operation signal generating device that generates an operation signal corresponding to the number of hits detected by the hit number detecting unit based on the correspondence relationship. The operation signal generation device according to claim 13,
An operation signal generation device further comprising a correspondence setting unit that sets a correspondence between the hit count and the operation signal and stores the correspondence in the correspondence storage. In the operation signal generation device according to claim 13 or 14,
The correspondence storage unit
Storing the correspondence between the number of hits and the operation signal for each processing system;
A processing system switching unit further selecting and switching one of the processing systems from a plurality of processing systems;
The operation signal generator is
An operation signal generation device that generates an operation signal associated with the detected number of hits based on the correspondence relationship in the selected processing system. In the operation signal generation device according to any one of claims 1 to 15,
An operation signal generation device further comprising setting means for setting operation of the electronic device based on an output signal of the vibration detection sensor to be valid or invalid.