JP2006203729A - Remote control transmitter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To completely intercept a powersource in the case of non-operation, and detecting the start of the operation without a delay at the time of starting the operation, thereby performing the operation of a remote controller without any incompatibility. <P>SOLUTION: The user can perform the operation of the remote control transmitter without any incompatibility by intercepting power supply from a power source part 4 to a control part 3 by a power supply part 6 when the user does not operate the remote control transmitter, preventing the consumption of the power supply when the remote controller is not yet operated and on the other hand, starting the power supply from the power source part 4 to the control part 3 by a power supply part 6 by an output signal of an operation detection part 5 having power generation functions when the user starts the operation of the remote control transmitter. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a remote control transmitter, and more particularly to a remote control transmitter having a power saving function for preventing battery consumption.

  A conventional remote control transmitter (see, for example, Patent Document 1) will be described with reference to the drawings. FIG. 10 is a block diagram for explaining an internal circuit of a conventional remote control transmitter. FIG. 11A and FIG. 11B are external views of a conventional remote control transmitter as viewed from the front side and the back side, respectively, and FIG. 12 is a partial cross-sectional view of the conventional remote control transmitter.

  As shown in FIG. 10, the internal circuit of the conventional remote control transmitter includes a power supply unit 401, a remote control transmission microcontroller IC circuit 403, a system clock oscillation circuit 404, a key matrix circuit 405, and an infrared remote control transmission output. Circuit 406. The power supply unit 401 is a part that supplies a DC voltage to operate the electric circuit of the remote control transmitter, and mainly uses a dry battery or a lithium battery, and supplies a DC voltage of about 2 to 3.5V. ing.

  Further, the remote controller transmission microcontroller IC circuit 403 receives a power supply from the power supply unit 401 and operates at a low voltage, and has a standby release function and a programmable timer by an infrared remote control transmission carrier generator and key input, It is a single chip type microcontroller that can output a transmission signal according to key input. In addition, the system clock oscillation circuit 404 includes a ceramic oscillator and an oscillation capacitor, and supplies a basic clock for the remote controller transmission microcontroller IC circuit 403 to perform a program operation.

The key matrix circuit 405 is composed of a plurality of buttons for the user of the remote control transmitter to control the electric device, and is arranged on the surface of the remote control transmitter to perform an operation corresponding to the key input on the transmission microcontroller IC. The circuit 403 can perform this.
Further, the infrared remote control transmission output circuit 406 operates by receiving power supply from the power supply unit 401. The remote control transmission output signal from the transmission microcontroller IC circuit 403 is externally converted into an infrared signal by an infrared diode as an infrared output element. Can be output.

  As shown in the external views of FIGS. 11A and 11B, the conventional remote control transmitter has an operation button 501 and an infrared output element 502. The operation button 501 includes a plurality of buttons that are operated by the user to control the electric device on the surface of the remote control transmitter, and performs an operation corresponding to the user's key input in the transmission microcontroller of FIG. This is performed by the IC circuit 403. Further, the infrared output element 502 outputs the remote control transmission output signal from the transmission microcontroller IC circuit 403 of FIG. 10 as an infrared signal necessary for controlling the electric device.

As shown in the cross-sectional view of FIG. 12, the internal structure of this conventional remote control transmitter includes a case cover front side 601, a case cover back side 602, a printed circuit board 603, a rubber 604 with a contact, An element 605 is provided. The housing cover front side 601 holds the printed circuit board 603, the rubber 604 with contacts, and the power supply unit 401 in FIG. 9, and is configured by an insulating material with a plurality of buttons that are operated on the surface to control the electrical equipment. Yes.

  Further, the housing cover back side portion 602 holds the printed circuit board 603 and the power supply unit 401 of FIG. 9 similarly to the case cover front side portion 601, and is stable when placed on a desk, a floor, or an upper flat portion of an electric device. It is processed into a shape that can be maintained.

  In addition, the printed circuit board 603 has electrical circuit components such as the remote controller transmission microcontroller IC circuit 403, the system clock oscillation circuit 404, and the infrared remote control transmission output circuit 406 shown in FIG. 10 mounted on one surface of the printed circuit board. The copper foil pattern thus formed is connected by soldering, and a conductively painted pattern corresponding to the rubber 604 with a contact is also formed.

  The rubber 604 with a contact is a rubber integrated with a plurality of buttons operated by the user to control the electrical equipment, and the conductive material formed on the surface of the printed circuit board 603 is below the buttons. A plurality of contacts arranged so as to correspond to the coating pattern are configured, and the operation according to the user's key input can be performed by the transmission microcontroller IC circuit 403 in FIG.

  Further, the infrared output element 605 can output a remote control transmission output signal from the transmission microcontroller IC circuit 403 of FIG. 10 as an infrared signal by an infrared diode.

  Next, the operation of the conventional remote control transmitter will be described. As shown in FIG. 10 to FIG. 10, the operation of the conventional remote control transmitter is as follows. First, when the battery used for the power supply unit 401 is attached to the remote control transmitter main body, the operation is performed on the surface of the remote control transmitter. Regardless of whether or not the key matrix circuit 405 corresponding to the arranged button is input, the power supply line from the power supply unit 401 to the remote control transmission microcontroller IC circuit 403 and the infrared remote control transmission output circuit 406 is always in a conductive state. To.

  In this state, when the operation button 501 in FIG. 11 is operated and there is an input to the key matrix circuit 405 shown in FIG. 10, the microcontroller IC circuit 403 detects this and outputs an infrared remote control signal output corresponding to the button. The infrared remote control output circuit 406 is instructed to output an infrared output signal from the infrared output element 502 shown in FIG.

  However, the conventional remote control transmitter has a problem in that power supply from the power supply unit 401 continues even when the remote control transmitter is not used.

  To solve this problem, as shown in FIG. 14, by providing a power switch 606 for conducting / cutting off the power line on the back of the remote control, the remote control transmitter is placed on the desk, floor, or upper flat part of the electrical equipment. When the user does not use the remote control transmitter, the power supply line from the power supply unit 401 to the remote control transmission microcontroller IC circuit 403 and the infrared remote control transmission output circuit 406 shown in FIG. Since the switch 407 is pushed by the weight of the remote control body, the switch 407 is cut off. This push button switch is a push-off type one-circuit / one-contact switch, and when the button is pressed, the contact is released and the circuit is cut off.

At this time, no voltage is supplied from the power supply unit 401 such as a dry battery or a lithium battery, and the remote controller transmission microcontroller IC circuit 403 and the infrared remote control transmission output circuit 406 are not operated and do not consume power. . In this state, even if the operation button 201 shown in FIG. 11 is operated, no voltage is supplied to the microcontroller IC circuit 403 or the like shown in FIG. 13, so that no remote control signal is output and power consumption is eliminated. It becomes possible.
JP 11-355153 A

  However, the place where the remote control transmitter is placed is not limited to being generally flat, and may be placed on a soft object such as a cushion. It is conceivable that the power switch 606 on the back side shown in FIG. 6 is not pushed in. In such a case, power consumption when the remote control transmitter is not operated cannot be eliminated.

  In order to solve the above problems, a remote control transmitter according to the present invention includes a power supply unit that supplies power of a power supply unit to a control unit based on an output signal of an operation detection unit having a power generation function that detects the start of a user's operation. It is equipped with. The operation detection unit and the power supply unit with this power generation function can detect the start of operation of the remote control transmitter without being affected by the situation where the remote control transmitter is placed. The purpose is to prevent power consumption at the time.

  The remote control transmitter of the present invention shuts off the power when the user does not operate the remote control transmitter and prevents the power from being consumed when the remote control is not operated, while the user starts operating the remote control transmitter. Since the supply of power from the power supply unit is started by the output signal of the operation detection unit having a power generation function, the user can operate the remote control transmitter without a sense of incongruity.

  The first invention operates an input unit corresponding to one or a plurality of functions, a display unit for displaying functions corresponding to the input unit, a control unit for controlling the entire remote control transmitter, and the entire remote control transmitter. In a remote control transmitter having a power supply unit that stores electric power to be operated, an operation detection unit that detects a user's operation start, and whether to start supplying the power of the power supply unit to the control unit by the output of the operation detection unit By providing a power supply unit that controls whether or not the remote control is not operated, the power supply is cut off, and immediately after the user picks up the remote control transmitter to start operating the remote control transmitter, the power supply unit Since the power to the remote control transmitter is turned on, it is possible to prevent the power source from being consumed when the remote control transmitter is not operated, and the user can operate the remote control transmitter without feeling uncomfortable.

  According to a second aspect of the invention, particularly in the first aspect of the invention, when the power supply unit once starts the power supply from the power supply unit to the control unit by the output of the operation detection unit, the output of the operation detection unit is output after the start. Even if the power supply is interrupted, the power supply is not cut off, so that the remote control transmitter is driven by the power supply unit after being activated by the operation detection unit, so that stable operation can be performed.

  In the third invention, particularly in the first and second inventions, the operation detection unit has a power generation function using vibration when the operation of the remote control is started, so that when the remote control is not operated, the power supply is completely The power consumption of the power supply unit can be stopped, so that it is possible to prevent the power supply unit from being consumed.On the other hand, power is supplied from the power supply unit to the remote control transmitter immediately after the remote control transmitter is obtained. The person can operate the remote control transmitter without feeling uncomfortable.

In the fourth aspect of the invention, particularly in the first to third aspects of the invention, the control unit does not detect the user's operation from the input unit, and after a certain time has elapsed, the power supply unit supplies power to the control unit. By stopping sending the signal to the power supply unit, when the remote control is not operated, the power consumption of the power supply unit can be completely stopped, so that the power supply unit can be prevented from being consumed.

  In the fifth invention, particularly in the first to third inventions, the control unit supplies power from the power supply unit to the control unit after the operation detection signal output from the operation detection unit is interrupted and a certain time has elapsed. By stopping sending the signal for performing the operation to the power supply unit, when the remote control is not operated, the power consumption of the power supply unit can be completely stopped, so that the power supply unit can be prevented from being consumed.

  In a sixth aspect of the invention, particularly in the first to third aspects of the invention, after the operation detection signal output from the operation detection unit is interrupted and a fixed time has elapsed, the control unit stops displaying the display unit, Even when the operation of the control unit cannot be completely stopped due to reasons such as a timer, it is possible to prevent the power source unit from being consumed by the display unit when the remote controller is not operated.

  In a seventh aspect of the invention, particularly in the first to sixth aspects of the invention, the control unit has an abnormality determination unit that compares an operation input from the input unit with an operation detection signal output from the operation detection unit. Is determined to be abnormal, by stopping sending a signal for power supply from the power supply unit to the control unit to the power supply unit, the remote control transmitter has received a key input for a reason other than the operation by the operator. Even in such a case, since the situation is detected and the power supply is shut off, the power supply unit can be prevented from being consumed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiment.

(Embodiment 1)
1 is a block diagram of a remote control transmitter according to Embodiment 1 of the present invention, FIG. 2 is an internal configuration diagram of an operation detection unit 5, FIG. 3 is a configuration diagram of a piezoelectric generator 10, and FIG. FIG. 5 is a configuration diagram of the power supply unit 6. Hereinafter, the operation of the remote control transmitter according to the first embodiment of the present invention will be described with reference to FIGS.

  As shown in FIG. 1, the control unit 3 controls the entire remote controller, and the control unit 3 includes an input unit 1 that transmits an input instruction from an operator, a display unit 2 that displays various control information, and a power supply unit. A power supply unit 6 for connecting or cutting off the power from 4 is connected. The power supply unit 6 is connected to the power supply unit 4 and an operation detection unit 5 that detects the start of the operation.

  Next, each process of the remote control transmitter when the operator starts the remote control operation will be described. When the operator holds the remote control transmitter, vibration is generated in the entire remote control transmitter. The operation detection unit 5 that has detected the vibration outputs a signal for performing power supply from the power supply unit 4 to the power supply unit 6. Hereinafter, how the operation detection unit 5 detects vibration and outputs a signal to the power supply unit 6 will be described.

  FIG. 2 is an internal configuration diagram of the operation detection unit 5. The operation detection unit 5 includes a piezoelectric generator 10 and a signal generation circuit 11. Piezoelectric generator 10 is supported in a remote control transmitter so as to vibrate. That is, when the operator picks up the remote control transmitter, the remote control transmitter swings, so that the voltage generated in the piezoelectric generator 10 is rectified in the signal generation circuit 11, The generated power is used to output a signal for instructing the power supply unit 6 that the operation of the remote control has been started.

  In order to ensure the operation of the signal generating circuit 11, both the positive and negative voltages generated by the piezoelectric generator 10 are used. Therefore, a rectifier circuit in the signal generating circuit 11 is a circuit in which a diode is combined with a bridge. It is desirable to use

  Next, a configuration example of the piezoelectric generator 10 will be described with reference to FIG. A piezoelectric power generator 10 shown in FIG. 2 is a cylindrical container with both ends closed. Piezoelectric ceramic plates PZT1 and PZT2 are disposed inside, and the piezoelectric ceramic plates PZT1 and PZT2 are generated by striking a steel ball 22. Is. The cushion plate 23 is bonded and bonded to one side surface of the container of the piezoelectric generator 10, and the piezoelectric ceramic plate PZT 1 is bonded only to the central portion of the cushion plate 23 using the adhesive material 24. Similarly, the piezoelectric ceramic plate PZT2 is bonded to the other side surface of the container so that the two faces each other. A protector plate 25 is fixed to the center of the opposing surfaces of these two piezoelectric ceramic plates. And the pipe 20 is arrange | positioned between both piezoelectric ceramic plates, and the steel ball 22 which can roll freely in this pipe 20 is provided.

  The piezoelectric ceramic plates PZT1 and PZT2 have two plate-like piezoelectric ceramic elements 21a and 21b having the same form (same material, same shape and same thickness), and the polarities of polarization of the ceramic elements 21a and 21b are reversed. Are joined together. By joining the ceramic elements 21a and 21b having the same form, the two ceramic elements 21a and 21b are subjected to flexural vibration with the joint surface as a center (a portion that does not expand and contract). In this case, if the ceramic element 21a on one side expands, the ceramic element 21b on the other side contracts and the electrodes of the output voltage are in the same direction, and the piezoelectric ceramic elements 21a and 21b are connected in series. It becomes.

  The piezoelectric ceramic elements 21a and 21b are known for use as a conversion element between mechanical energy and electrical energy, and many materials are known to exhibit the piezoelectric effect, both inorganic and organic. As a material at a practical level, there is a material such as ceramic PZT (piezoelectric ceramics).

  Piezoelectric ceramic elements are elements in which high voltage direct current is applied to polycrystals to generate remanent polarization and have piezoelectricity, and the basic piezoelectric constant can be changed quite freely depending on the composition. Zinc acid-based piezoelectric ceramic elements have a wide composition ratio and a wide selection range of additives, and are suitable as a power generator for a remote control transmitter as in the present invention.

  By the way, when flexural vibration is performed around the joint surface, one of the piezoelectric ceramic elements 21a (or 21b) performs both expansion and contraction, and the polarization is not canceled out efficiently. Power generation is performed. The electric current as the generated electric energy is taken out using the lead wire 26.

  The cushion plate 23 is a synthetic resin material, a rubber material, or a soft material in which these are sponged. The reason why the piezoelectric ceramic plate 21 is fixed using such a cushion plate 23 and only the central portion of the cushion plate 23 using the adhesive 24 is to prevent the vibration of the piezoelectric ceramic plate 21 from being attenuated. When the piezoelectric ceramic plate 21 vibrates, the member that supports the piezoelectric ceramic plate 21 becomes a factor that attenuates the vibration of the piezoelectric ceramic plate 21. In order to remove this attenuation factor, the piezoelectric ceramic plate is used as much as possible by using the cushion plate 23. 21 is left free.

  By using the cushion plate 23, the natural vibration of the piezoelectric ceramic plate 21 continues for a long time, so that the power generation efficiency is improved. Further, the cushion material reduces the impact applied to the piezoelectric ceramic plate 21. The protector plate 25 is made of metal, synthetic resin, or the like, and protects the piezoelectric ceramic plates PZT1 and PZT2 from hitting the steel balls 22.

In the case of the remote control transmitter equipped with the piezoelectric generator 10 having such a configuration, the vibration steel ball 22 rolls in the pipe 20 by the operator holding the remote control for the purpose of operating the remote control. The piezoelectric ceramic plates PZT1 and PZT2 are beaten and impact energy due to collision is applied. The piezoelectric ceramic plates PZT1 and PZT2 are excited to vibrate and are repeatedly expanded and contracted to generate AC electricity.

  Here, as the hitting body, the steel ball 22 is arranged in the pipe 20 to hit the piezoelectric ceramic plates PZT1 and PZT2. However, the material and shape of the hitting body are limited to steel balls. Instead, a heavy object such as a columnar shape or an egg shape may be used. Further, not only the pipe 20 but also a configuration in which the hitting body moves along the rail may be used as long as the hitting body can move freely. In addition, instead of the pipe 20, a spring material (upward or downward) is used, one end of the spring material is fixed, and the steel ball 22 is attached to the other end. The plates PZT1 and PZT2 can be beaten.

  FIG. 4 shows a circuit of the signal generation circuit 11 that rectifies the electricity generated by the piezoelectric generator 10 and generates a signal for instructing the power supply unit 6 to supply power. The signal generation circuit 11 includes a rectifier diodes D1 to D6 and a photocoupler PC1 for transmitting a signal generated by the piezoelectric generator 10 to the power supply unit 6. The electricity generated by the PZT1 of the piezoelectric generator 10 is full-wave rectified by the diodes D1 to D3, and the electricity generated by the PZT2 of the piezoelectric generator 10 is full-wave rectified by the diodes D4 to D6. When the full-wave rectified electricity exceeds the threshold value of the photocoupler PC1, the PC1 is turned on, which becomes a signal for instructing the start of power supply.

  The operation when the power supply unit 6 receives a signal for instructing power supply from the operation detection unit 5 will be described with reference to FIG. The power supply unit 6 includes a SW control determination unit 30 and a SW unit 30. The control unit 3, the operation detection unit 5, and the SW unit 31 are connected to the SW control determination unit 30. When a power connection command signal is input from the control unit 3 or a signal for instructing power supply is input from the operation detection unit 5, the SW control determination unit 30 outputs a power supply signal to the SW unit 31 according to the signal. When the SW unit 31 is turned on, power supply from the power supply unit 4 to the control unit 3 is started.

  When the supply of power from the power supply unit 4 is started, the control unit 3 outputs a power connection command signal for continuing the conduction of the SW unit 31 to the SW control determination unit 30. As a result, even when the output of the piezoelectric generator 10 is reduced due to vibration conditions and the signal for commanding power supply is interrupted, the power supply from the power supply unit 4 is continued. It can be performed stably.

  Next, the operation when the operation of the remote control transmitter by the operator is completed will be described. The control unit 3 stops the power connection command signal for the SW control determination unit 30 when the operation input from the input unit 1 is interrupted and a predetermined time elapses. The SW control determination unit 30 that has detected the stop of the power connection command signal stops the power supply signal to the SW unit 31. The SW unit 31 that has detected the stop of the power supply signal from the SW control determination unit 30 blocks the power supply line from the power supply unit 4 to the control unit 3. As a result, the power supply unit is not consumed when the remote control transmitter is on standby.

(Embodiment 2)
FIG. 6 is a block diagram of a remote control transmitter according to the second embodiment of the present invention. FIG. 7 is a flowchart showing the processing of the control unit 3 for stopping the operation of the remote control transmitter when the operation by the operator is finished and preventing the power source unit 4 from being consumed. Hereinafter, the operation of the remote control transmitter according to the second embodiment of the present invention will be described with reference to FIGS.

Here, the operations of the input unit 1, the display unit 2, the power supply unit 4, the operation detection unit 5, and the power supply unit 6 are the same as those described in the first embodiment, and thus are omitted. The second embodiment is characterized in that the output of the operation detection unit 5 is input to the control unit 3 in addition to the power supply unit 6. Since the part different from the operation of the first embodiment is when the operation of the remote control transmitter by the operator is finished, the operation of this part will be described with reference to the flowchart of FIG. The process by the flowchart demonstrated here is performed for every fixed time.

  In st1, the signal from the operation detection unit 5 is examined. Since the output of the operation detection unit 5 is intermittently vibrated while the operator operates the remote control transmitter, the output signal of the operation detection unit 5 commands the power supply while fluctuating and intermittent. A signal is input. In other words, if the operator is holding the remote control transmitter, a signal for instructing power supply is input, but if the operator has not been operated because the operation has been completed, the signal for instructing power supply is input. Not. If a signal for instructing power supply is not input, the process proceeds to st2. On the other hand, if a signal for instructing power supply is input, the process proceeds to st5.

  In st2, in order to count the time when there is no input from the operation detection unit, the current counter is incremented by 1, and the process proceeds to st3. In st3, it is determined whether or not the counter value updated in st2 exceeds a preset upper limit value. If exceeded, the process proceeds to st4, and if not exceeded, the process ends. In st4, the power connection command signal for the power supply unit 6 is stopped and terminated. On the other hand, in st5, since the operator is currently operating the remote control transmitter, the counter that counts the time when there is no input from the operation detection unit is set to 0, and the process ends.

  In FIG. 5, the SW control determination unit 30 that has received the stop of the power connection command signal instructs the SW unit 31 to turn off the power. The SW unit 31 that has received the power-off command from the SW control determination unit 30 blocks the power supply line from the power supply unit 4 to the control unit 3. As a result, the power supply unit is not consumed when the remote control transmitter is on standby.

(Embodiment 3)
FIG. 8 is a block diagram of a remote control transmitter according to Embodiment 3 of the present invention. Since the process at the time of starting and stopping the remote control transmitter is the same as that described in the first and second embodiments, the description thereof is omitted.

FIG. 9 shows that the operation of the remote control transmitter is stopped when it is continuously input by the input unit 1 due to other reasons such as the remote control transmitter being underlayed by something else. FIG. 6 is a flowchart showing processing of the control unit 3 for preventing the power supply unit from being consumed. FIG.
The process of the control part 3 is demonstrated according to the flowchart of FIG. The process by the flowchart demonstrated here is performed for every fixed time.

  Steps st1 to st6 are steps for determining whether or not the remote control transmitter is currently in the hands of the operator based on a signal for instructing the power supply of the operation detection unit 5. In st1, a signal for instructing power supply from the operation detection unit 5 is examined. When the operator holds the remote control transmitter, a signal for instructing power supply is input, but when the operator is placed, no signal is input. If no signal is input, the process proceeds to st2. If a signal is input, the process proceeds to st5. In st2, the time when there is no input from the operation detection unit is counted, and the process proceeds to st3. In st3, it is determined whether or not the count value in st2 (time when there is no input from the operation detection unit) exceeds a preset upper limit value. If it has exceeded, go to st4, and if not, go to st7. In st4, it is determined that the current operation state is not operated by the operator, and the process proceeds to st7.

On the other hand, in st5, since the operator is currently operating the remote control transmitter, the value counted in st2 (the time during which no signal for commanding power supply from the operation detection unit is input) is obtained. The process proceeds to st6 with 0, and in st6, it is determined that the current operation state is an operation by the operator, and the process proceeds to st7.

  Steps st7 to st12 are steps for determining whether or not there is an input by the input unit 1. In st7, the signal from the input unit 1 is examined. When the operator is operating the remote control transmitter, a key input signal is intermittently obtained, but when the operator is not operating, a key input signal is not obtained. If a key input signal cannot be obtained, the process proceeds to st8. If a key input signal is obtained, the process proceeds to st11. In st8, the time when there is no input from the input unit 1 is counted, and the process proceeds to st9. In st9, it is determined whether or not the count value in st8 (time when there is no key input from the input unit 1) exceeds a preset upper limit value. If it has exceeded, go to st10, otherwise go to st13. In st10, it is determined that the current input state is a state where there is no key input, and the process proceeds to st13.

  On the other hand, in st11, since the operator is currently inputting the remote control transmitter, the counter value counted in st8 (time when there is no key input from the input unit 1) is set to 0 and the process proceeds to st12. In st12, it is determined that the current input state is a state where there is a key input, and the process proceeds to st13. After st13, an abnormal state is determined from the current operation state and the current key input state, and processing corresponding to that is executed.

  In st13, it is determined whether or not the current state is abnormal. If the current operation state is a state where there is no operation by the operator determined in st4 and the current key input state is a state where there is a key input determined in st12, it is determined that there is an abnormality and the process proceeds to st14. On the other hand, if this condition is not satisfied, the process is terminated. In st14, the power connection command signal is stopped so as to stop the power supply to the power supply unit 6.

  With the flow as described above, it is possible to prevent the power supply unit from being consumed when a key is pressed other than by an operation by the operator.

The remote control transmitter of the present invention can be applied to remote control transmitters of various electric and electronic devices, and particularly has a power saving function, so that the transmitter can be miniaturized by using a large amount of power when not operated or using a small battery. This is useful in some cases.

Block diagram of a remote control transmitter according to Embodiment 1 of the present invention The internal block diagram of the operation detection part 5 by Embodiment 1 of this invention Configuration diagram of piezoelectric generator 10 according to the first embodiment of the present invention 1 is a circuit diagram of a signal generation circuit 11 according to a first embodiment of the present invention. Configuration diagram of power supply unit 6 according to Embodiment 1 of the present invention Block diagram of a remote control transmitter according to Embodiment 2 of the present invention The flowchart which shows the process of the control part 3 in the case of stopping operation | movement of the remote control transmitter by Embodiment 2 of this invention. Block diagram of a remote control transmitter according to Embodiment 3 of the present invention The flowchart which shows the abnormality time determination process of the control part 3 by Embodiment 3 of this invention. Block diagram of the internal circuit of a conventional remote control transmitter External view of a conventional remote control transmitter viewed from the front and back sides Partial sectional view of a conventional remote control transmitter Block diagram of the internal circuit of a conventional remote control transmitter Partial sectional view of a conventional remote control transmitter

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Input part 2 Display part 3 Control part 4 Power supply part 5 Operation detection part 6 Electric power supply part

Claims (7)

An input unit corresponding to one or a plurality of functions, a display unit for displaying the function corresponding to the input unit, a control unit for controlling the entire remote control transmitter, and power for operating the entire remote control transmitter are stored. A remote control transmitter including a power supply unit, wherein the remote control transmitter detects an operation start of a user and supplies an electric power of the power supply unit to the control unit by an output of the operation detection unit A remote control transmitter comprising a power supply unit that controls whether or not to perform. Once the power supply unit starts supplying power from the power supply unit to the control unit based on the output of the operation detection unit, the power supply unit also supplies power even when the operation detection signal of the operation detection unit is interrupted after the start. The remote control transmitter according to claim 1, wherein the remote control transmitter is not stopped. 3. The remote control transmitter according to claim 1, wherein the operation detection unit has a power generation function using vibration when a remote control operation is started. 4. After the control unit no longer detects a user operation from the input unit and a predetermined time has elapsed, a signal for supplying power from the power supply unit to the control unit is output to the power supply unit. 4. The remote control transmitter according to claim 1, wherein the remote control transmitter is stopped. After the operation detection signal output from the operation detection unit is interrupted and a predetermined time elapses, the control unit sends a signal to the power supply unit to supply power from the power supply unit to the control unit. The remote control transmitter according to any one of claims 1 to 3, wherein transmission is stopped. 4. The control unit according to claim 1, wherein the control unit stops the display of the display unit after the operation detection signal output from the operation detection unit is interrupted and a predetermined time elapses. A remote control transmitter according to the above. The control unit includes an abnormality determination unit that compares an operation input from the input unit and an operation detection signal output from the operation detection unit, and when the abnormality determination unit determines that an abnormality has occurred, 7. The remote control transmitter according to claim 1, wherein the remote control transmitter stops sending a signal for implementing power supply to the control unit to the power supply unit. 8.

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