JP4842905B2 - Data receiver - Google Patents

Description

  The present invention operates only the portion related to the reception of infrared light in the standby state with the power off, and in particular, reliably encodes the encoded data against infrared light including the encoded data emitted in the standby state. The present invention relates to a data light receiving device that can be held.

  Conventionally, electrical devices (television devices, recording devices, etc.) that can be remotely operated with a remote control device (hereinafter referred to as a remote control device) can be activated in response to a power-on operation with the remote control device even when the power is off. Therefore, power supply control is generally performed in which power is supplied only to a portion related to reception of infrared light emitted from a remote control device and is activated. In addition, some recent television apparatuses, recording apparatuses, and the like have a model that can receive image data and the like wirelessly. As a wireless system, wireless LAN, Bluetooth (registered trademark), infrared communication (IrDA ( Infrared Data Association) format).

  As described above, devices that transmit image data and the like wirelessly include digital cameras, mobile phones with an imaging function, and the like. It is a specification to transmit data. The receiving device includes a printer, a television device, a recording device, a display device, and the like. These devices decode the received encoded data and perform processing related to output (printout, image display, etc.). Process).

The following Patent Document 1 discloses a video broadcast transmission / reception system that suppresses power consumption in a power-off state. Japanese Patent Application Laid-Open No. 2004-228688 discloses the content of converting image data into IrDA modulated data and wirelessly transmitting the image data in the IrDA format.
JP 2002-314897 A Japanese Patent Laid-Open No. 11-75102

  Among the wireless methods for sending image data and the like wirelessly, the transmission side device and the receiving side device establish a connection for wireless communication, and then establish a connection for establishing communication for image data and the like. There is a method of transmitting image data or the like from the transmission side device without performing the above. A specific example of the latter wireless system is IrSimple (infrared communication technology established as an international standard by IrDA).

  In IrSimple communication, a method of transmitting image data or the like suddenly without establishing a connection as described above (referred to as unimode) is adopted. There is a problem that it cannot be confirmed whether or not the message has been transmitted. Furthermore, since various devices that support IrSimple are not designed to temporarily store data even if they are received in a power-off standby state, they are transmitted when the receiving device is powered off. If the device on the side transmits data, the transmitted data may be lost.

The present invention has been made in view of such a problem. Even when a receiving-side apparatus that supports a method of communicating encoded data wirelessly without establishing a connection is in a power-off state, the encoding is performed. It is an object of the present invention to provide a data light receiving device in which a data receiving portion is operated to store data received when the power is turned off.
In addition, the present invention provides a composite in which a reception-side device that supports a method of communicating encoded data wirelessly without establishing a connection can notify the outside of the reception when the encoded data is received. An object of the present invention is to provide a data output device.

In order to solve the above-described problems, a data receiving device according to the present invention includes a light receiving unit capable of receiving infrared light including encoded data, and decoding encoded data included in the infrared light received by the light receiving unit. decoding means for reduction, and output processing means for performing output processing of the decoded data the decoding means has decoded, performs power feeding into the apparatus by the power from the power supply, power supply to perform the control according to the power supply of its And a data storage means for storing data, wherein the power supply control means makes the output processing means non-powered, the light receiving means, the decoding means, and the data receiving means. Power supply control can be performed in a first power supply state in which power is supplied to the data storage means. When the light receiving means receives infrared light including encoded data in the first power supply state, the data storage is performed. It means, and performs the storage of received light data according to the encoded data contained on the received infrared light.

  In the present invention, the first power supply state for supplying power to a portion (light receiving means, decoding means, and data storage means) related to reception (light reception) of infrared rays (infrared light) including encoded data can be performed, When infrared light including encoded data is received in the first power supply state, the data storage means stores the received encoded data, so that the receiving device is in a standby state (most of the devices in the non-powered state). Even in the power supply state), the received encoded data can be reliably held by the data storage means.

  In the data light receiving device according to the present invention, when the light receiving unit receives infrared light including encoded data in the first power supply state, the data storage unit stores the code included in the received infrared light. The decrypted data obtained by decrypting the decrypted data by the decrypting means is stored.

  In the present invention, since the encoded data relating to the received infrared light is decoded by the decoding means and then stored in the data storage means, there is no need for decoding when outputting by the output processing means. Thus, the output process can be smoothly performed without waiting for the decryption process.

  Furthermore, the data light receiving device according to the present invention performs power supply control for supplying power to the output processing means when the light receiving means receives infrared light including encoded data in the first power supply state. The output processing means, which is configured to supply power, reads out the decoded data stored in the data storage means and performs output processing.

  In the present invention, when infrared light including encoded data is received in the first power supply state, power is automatically supplied to the output processing means, and decoded data combined from the encoded data is stored. The decrypted data is read out from the data storage means to perform output processing. Therefore, even if the data light receiving device is in the first power supply state corresponding to power saving, once the infrared light including the encoded data is received, the output processing means is also supplied with power and the decoded data is output. Since the process is performed, the received data can be smoothly output while ensuring power saving.

  Furthermore, the data light receiving apparatus according to the present invention detects whether or not decoded data is stored in the data storage means when the power supply control means performs power supply control for supplying power to the output processing means. And the output processing means reads the decoded data from the data storage means when the detection means detects that the decoded data is stored in the data storage means.

  In the present invention, when the user turns on the power of the remote control device, the output processing means is in a power supply state. In this case, if the decoded data is stored in the data storage means, the output is decoded from the data storage means. Since the encrypted data is read and output processing is performed, the decrypted data output processing can be performed in accordance with the activation of the output processing means. Therefore, the decrypted data stored in the data storage means can be output after the output processing means is activated, and an output process suitable for the user's convenience can be provided.

  In addition, the data light receiving device according to the present invention includes notification output means for outputting a notification that the infrared light including the encoded data is received when the light receiving means receives the infrared light including the encoded data. It is characterized by that.

  In the present invention, when infrared light including encoded data is received, a notification output indicating that the light has been received is output. Therefore, even in a wireless communication system that does not establish connection for wireless communication, a device on the transmission side Can confirm that the transmitted decrypted data has been successfully received. As examples of notification output, it is conceivable to turn on an indicator lamp composed of an LED or the like and to output a specific sound. Such a notification output is particularly suitable for light reception in the first power supply state. However, even if the notification output is performed for light reception when the entire data light receiving device is operating in the power-on state. Good.

In the present invention, by performing power supply control in the first power supply state in which power is supplied only to the location related to light reception, power consumption in the standby state can be suppressed, and infrared including encoded data in the first power supply state If the light is received, the data related to the light reception is stored in the data storage means, so that the encoded data transmitted in the unimode can be reliably saved.
In the present invention, since the encoded data relating to the received infrared light is decoded by the decoding unit and then stored by the data storage unit, a smooth output process can be realized when performing the output process.

In the present invention, when infrared light including encoded data is received in the first power supply state, power is automatically supplied to the output processing means, and the decoded data is read from the data storage means and output processing is performed. Thus, the decoded data can be automatically output while maintaining power saving.
In the present invention, if the output processing unit is in a power supply state and the decoded data is stored in the data storage unit, the decoded data is read from the data storage unit and the output process is performed. Therefore, the decrypted data output process can be performed in accordance with the user's power-on operation or the like.

  In the present invention, when infrared light including encoded data is received, a notification output indicating that the light has been received is output. Therefore, even if transmission is performed in unimode, the user of the transmission-side device can use the data light-receiving device. It can be confirmed by the notification output that the transmitted data has been successfully received, and the user's peace of mind can be enhanced with respect to the transmission in unimode.

  FIG. 1 is a block diagram showing a main configuration of a television apparatus 10 according to an embodiment of the present invention. The television device 10 corresponds to the data light receiving device of the present invention, and can receive image data and the like sent from the outside by IrSimple which is a data communication method using infrared light. In addition, the television apparatus 10 includes a light reception processing circuit 11, an output processing circuit 20, and a power supply control unit 30 as internal circuits related to the present invention, and always supplies power to the light reception processing circuit 11 in a standby state with the power off. Even in a standby state, communication with an external device by IrSimple is possible, and data sent from the external device can be received and held.

  In the present embodiment, the mobile phone 1 with an imaging function is used as an external device (transmission side device), and the mobile phone 1 has an operation unit 2 including a plurality of keys below the front surface of the housing 1a. At the same time, a light emitting unit (transmitting unit) 3 is provided at the front end of the housing 1a. In the cellular phone 1, by appropriately operating the operation unit 2, the captured image data is encoded, and infrared light including the encoded data is emitted from the light emitting unit 3 by the IrSimple communication method. Yes.

  The light reception processing circuit 11 of the television device 10 receives infrared light by IrSimple, the output processing circuit 20 performs display output processing of image data, and the power supply control unit 30 receives light reception processing. Control for supplying power to the circuit 11 and the output processing circuit 20 is performed. In FIG. 1, solid arrows indicate the flow of data, and broken arrows indicate the flow of control signals or instruction signals.

  The power supply control unit 30 of the television device 30 functions as a power supply control unit that performs control related to power supply in the device, and is connected to a commercial power source (AC 100V) (not shown) to convert AC 100V into DC power of a predetermined voltage. When the television apparatus 10 is in a standby state in which the power is off, the converted DC power is controlled to supply power only to the light receiving processing circuit 11 while the output processing circuit 20 is not supplied with power in the first power supply state. Further, when a power-on operation is performed in the television apparatus 10 or when light reception including encoded data described later is received, the power supply control unit 30 adds to the light reception processing circuit 11 and the output processing circuit 20. Control to supply power to Note that the power supply state switching control associated with the reception of the encoded data is performed based on a control signal sent from the light reception processing circuit 11 to the power supply control unit 30.

  The light receiving processing circuit 11 includes a light receiving unit (corresponding to light receiving unit) 12, a decoding processing unit (corresponding to decoding unit) 13, a memory (corresponding to data storing unit) 14, a memory controller 15, a microcomputer unit 16, and a light emitting unit. Part 17 and the like. The light receiving unit 12 receives infrared light including encoded data emitted from the outside, and has a configuration in which a light receiving element such as a photodiode is mounted on a substrate including a light receiving processing circuit.

  The decode processing unit 13 performs a process of decoding the encoded data included in the infrared light received by the light receiving unit 12, and sends the decoded data to the memory 14. In addition, the decoding process part 13 is performing the decoding process with respect to each data sent from the light-receiving part 12, and when the decoding process of the data encoded based on the IrSimple standard can be performed, that is said Is transmitted to the microcomputer unit 16, and when the decryption process cannot be performed, the microcomputer unit 16 is not particularly transmitted.

  The memory 14 temporarily stores and saves the decoded data combined by the decoding processing unit 13 in a state where power is supplied to the light receiving processing circuit 11, and the stored decoded data is stored in the output processing circuit. 20 can be read out. Note that the memory 14 has a storage capacity capable of storing image data corresponding to several tens to several hundreds of images. The memory controller 15 (corresponding to the detecting means) manages the storage and storage state of the data in the memory 14. In particular, when the power supply control unit 30 starts to supply power to the output processing circuit 20, the memory controller 15 decodes the memory 14. It is detected whether or not digitized data is stored, and a process for notifying the output processing circuit 20 of the detection result is performed.

  Further, the microcomputer unit 16 performs instruction control to switch the power supply state of the power supply control unit 30 and, when the light receiving unit 12 receives infrared light including encoded data based on IrSimple, it relates to a notification output to that effect. It's control. When the microcomputer unit 16 is in the default setting state and the power supply control unit 30 performs power supply in the first power supply state, the decoding processing unit is accompanied by the reception of infrared light including the encoded data in the light receiving unit 12. When it is informed from 13 that the encoded data has been decoded, the output processing circuit 20 performs a process of outputting an instruction to start power supply to the power supply control unit 30, and the output processing circuit 20 is accompanied by power supply. When activated, a process of outputting an instruction to start the process of reading the decoded data stored in the memory 14 to the output processing circuit 20 is performed. It should be noted that the microcomputer unit 16 has been set by the user so that it does not start in conjunction with the reception of infrared light including encoded data (a state in which the standby state is maintained) by setting conditions of the output processing circuit 20 described later. For example, the instruction control as described above is not performed.

  In addition, regarding the infrared light reception notification output including the encoded data, the microcomputer unit 16 is connected to a light emitting unit 17 (corresponding to a notification output unit) composed of LEDs, and the encoded data is received from the decoding processing unit 13. When it is notified that the decryption process has been performed, the microcomputer unit 16 performs control to cause the light emitting unit 17 to blink and emit light a plurality of times. The light emitting unit 17 is attached so as to be exposed on the front surface of a housing (not shown) of the television device 10, and the user of the transmission side device (for example, the mobile phone 1) transmits infrared light including data to IrSimple. Even when the data is transmitted in the unimode, the light emitting unit 17 blinks a plurality of times as described above, so that it is possible to confirm whether or not the transmitted data has been successfully received by the television device 10.

  Although not shown, the light receiving processing circuit 11 also includes an infrared remote control light receiving unit including an operation signal emitted from a remote control device for remote operation of the television device 10, and the first power supply state When the power button provided on the remote control device is turned on, the effect of the on operation is finally transmitted to the power supply control unit 30 through the remote control light receiving unit, and the power supply control unit 30 starts to supply power to the output processing circuit 20. It is like that.

  On the other hand, the output processing circuit 20 corresponds to an output processing means, and includes a main control unit 21, an operation unit 22, an output system circuit unit 23, a display unit 24, and the like. In FIG. 1, the contents of the output processing circuit 20 are shown only for the portions related to the present invention, but the output processing circuit 20 includes a television broadcast receiving unit, an audio output processing unit, and the like. Suppose that

  The operation unit 22 has various operation keys such as a power button, up / down / left / right keys, and an enter key. When the power button is turned on, a power supply control unit is connected to the output processing circuit 20 by a hardware electric circuit. Power supply is started from 30. When various operation keys of the operation unit 22 or various operation keys provided on the above-described remote control device are operated in a state where power is supplied to the output processing circuit 20, the operation content is transmitted to the main control unit 21. It is supposed to be.

  The main control unit 21 performs overall control processing of the output processing circuit 20 in accordance with the operation content of the operation unit 22 or the remote control device, and receives (receives) light from the light reception processing circuit 11 in the present invention. A control process for displaying and outputting the decrypted data (for example, image data) on the display unit 24 is performed. In addition, the main control unit 21 can set two patterns of the power supply state of the power supply control unit 30 related to the display output.

  The first pattern is set as a default, and when the light receiving processing circuit 11 receives infrared light including encoded data in the first power supply state, the output processing circuit 20 is also fed in conjunction with the received light. , And the activated main control unit 21 reads the decoded data stored in the memory 14 of the light receiving processing circuit 11 and performs control related to display output. In the first pattern, as described above, the power supply control unit 30 starts to supply power to the output processing circuit under the control of the microcomputer unit 16 of the light receiving processing circuit 11, and the main control unit 21 activated by the start of power supply is In response to a read instruction from the microcomputer unit 16 of the light reception processing circuit 11, a read process of the decoded data stored in the memory 14 is performed. The main control unit 21 sends the read decoded data to the output system circuit unit 23.

  In the second pattern, even if the light reception processing circuit 11 receives infrared light including encoded data in the first power supply state, power supply to the output processing circuit 20 is not started and the standby state (first power supply) State) is maintained. In this case, the main control unit 21 receives the infrared light including the encoded data by the light receiving processing circuit 11 and the microcomputer unit 16 performs the output processing even if the decoding processing unit 13 performs the decoding processing (decoding processing). The instruction output of the microcomputer unit 16 is limited in advance so as not to issue an instruction to start power supply to the circuit 20 to the power supply control unit 30.

  The second pattern as described above can be set on the menu screen 35 shown in FIG. Menu screen data corresponding to the menu screen 35 is stored in an internal memory (not shown) of the main control unit 21, and the main control unit is set by a predetermined setting operation of the operation unit 22 by the user or a setting operation on a remote control device (not shown). 21 displays the menu screen 35 on the display unit 24 so that the setting can be performed.

  The menu screen 35 is an operation state setting menu related to data reception based on IrSimple, and includes a start button 35a, a standby state 35b, a determination button 35c, and a return button 35d. These buttons 35a to 35d are selected when the enter key is operated while the cursor is positioned on each button by operating the up and down keys of the operation unit 22 or a remote controller (not shown). The start button 35a is a button for selecting the content of the first pattern described above set by default, and the standby maintenance button 35b is for selecting the content of the second pattern described above. When the determination button 35c is selected in a state where any one of the buttons 35a and 35b is selected, the contents (pattern) corresponding to any one of the buttons 35a and 35b are set. When the return button 35d is selected, the display is switched to a main menu screen (not shown).

  Further, the main control unit 21 shown in FIG. 1 causes the power supply control unit 30 to supply power to the output processing circuit 20 when the user performs an ON operation on the power button of the operation unit 22 or a remote control device (not shown). If the detection result sent from the memory controller 15 of the light receiving processing circuit 11 indicates that the decoded data is stored in the memory 14, the process of reading the decoded data from the memory 14 is performed. . The read decoded data is sent to the output path 23.

  The output system circuit unit 23 performs predetermined processing to display an image corresponding to the decoded data (image data) sent from the main control unit 21 on the display unit 24. When a plurality of image data are sent, the output system circuit unit 23 displays an image to be displayed on the display unit 24 in accordance with the operation of the operation unit 22 or the like or the contents preset in the main control unit 21. A process of switching sequentially is performed.

  The flowchart in FIG. 3 is a summary of a series of processing contents performed on the infrared light emitted from the outside by the light receiving processing circuit 11 of the television apparatus 10 in the first power supply state. This flowchart corresponds to the setting (default setting) for supplying power to the output processing circuit 20 in response to reception of encoded data. Hereinafter, the processing procedure related to light reception will be described in accordance with this flowchart.

  First, the television apparatus 10 determines whether or not infrared light is received by the light receiving unit 12 of the light receiving processing circuit 11 (S1). If there is no light reception (S1: No), the system waits for light reception, and if infrared light is received (S1: Yes), can the data included in the received infrared light be decoded (decoded) by the decoding processing unit 13? It is determined whether or not (S2).

  If the decoding is impossible (S2: No), the data included in the received infrared light cannot be displayed and output by the television device 10, so that it is not necessary to start the output processing circuit 20, so the processing is performed. Will end. In addition, when decoding is possible (S2: Yes), the decoding processing unit 13 notifies the microcomputer unit 16 that decoding has been performed, and sends the decoded data (decoded data, for example, image data) to the memory 14, Data related to light reception is stored in the memory 14 (S3). The microcomputer unit 16 controls the light emitting unit 17 to blink (S4), outputs a power supply start instruction to the output processing circuit 20 to the power supply control unit 30 (S5), and further outputs the output processing circuit 20. In response to the activation, an instruction to read the data stored in the memory 14 is output to the main control unit 21 (S6).

  The main control unit 21 activated by the power supply control unit 30 in response to power supply reads out the decoded data (image data) stored in the memory 14 in accordance with an instruction from the microcomputer unit 16 (S7), and outputs the read image data. The image is sent to the system circuit unit 23 and an image corresponding to the image data is displayed on the display unit 24 (S8). As described above, when receiving the infrared light including the encoded data based on IrSimple, the television device 10 according to the present embodiment first causes the light emitting unit 17 to blink and emit light, so that transmission is performed regardless of transmission in the unimode. The user can be notified that the data has been successfully received, and the user can feel secure. Further, even if the data is received in the first power supply state, the decoded data is temporarily stored in the memory 14 in the light receiving processing circuit 11 in which power is supplied in the first power supply state. Even in the case of data reception at, the received data is not lost, and the received data can be held securely until the entire apparatus is activated.

  Furthermore, since it is in a state of waiting for data reception in the first power supply state, it is possible to suppress an increase in power consumption of the television device 10 and output in response to reception of encoded data (image data) according to IrSimple. Since power supply to the processing circuit 20 is started, the output processing of the output processing circuit 20 is activated, and an image related to the received image data is automatically displayed. Therefore, the user on the transmission side (user of the mobile phone 1) The captured image can be confirmed on the large display unit 24 of the television device 10 simply by performing the transmission process.

  2 is set on the menu screen 35 of FIG. 2, the process of the flowchart shown in FIG. 3 is performed from the stage of S1 to the stage of S4. .

  In addition, this invention is not limited to embodiment mentioned above, The application of a various modification is assumed. For example, in the first power supply state, a sound output unit other than the light emitting unit 17 shown in FIG. 1 is used as a notification output unit for notifying and outputting to the user on the transmission side that infrared light including encoded data has been received. And a notification sound may be output from the sound output unit to notify the user. Further, in the above-described embodiment, the data light receiving device according to the present invention has been described in the case of the television device 10, but other data output devices besides the television device 10 are applied as the data light receiving device according to the present invention. It is possible.

  Examples of applicable devices include a printer and a recording device. When applied to a printer, the output system circuit unit 23 and the display unit 24 in FIG. 1 are replaced with a processing circuit unit related to print output of image data. It will be. In addition, when applied to a recording apparatus, the output system circuit unit 23 and the display unit 24 in FIG. 1 perform processing for outputting and storing image data in a storage device such as a hard disk device, or a television device. It is replaced with an external output unit or the like to which a display device is connected.

  Further, depending on the specifications of the data light receiving device according to the present invention, it may be possible to store the encoded data included in the infrared light received by the light receiving unit 12 as it is in the memory 14 without decoding. In this case, since the encoded data stored in the memory 14 is decoded when the output process is performed, there is an advantage that the processing load at the time of data reception can be reduced.

It is a block diagram which shows the principal part of the television apparatus which concerns on embodiment of this invention. It is the schematic which shows a menu screen. It is a flowchart which shows the processing content with respect to the light reception in a 1st electric power feeding state.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Television apparatus 11 Light reception processing circuit 12 Light reception part 13 Decoding processing part 14 Memory 15 Memory controller 16 Microcomputer part 17 Light emission part 20 Output processing circuit 21 Main control part 22 Operation part 23 Output system circuit part 24 Display part 30 Power supply control part

Claims (5)

Light receiving means capable of receiving infrared light including encoded data, decoding means for decoding encoded data contained in infrared light received by the light receiving means, and decoding decoded by the decoding means and output processing means for performing output processing of the data, it performs power feeding into the apparatus by the power from the power source, a data receiving apparatus and a power supply control means for performing control relating to the feeding of their,
Data storage means for storing data;
The power supply control means makes it possible to perform power supply control in a first power supply state in which the power is not supplied to the output processing means and power is supplied to the light receiving means, the decoding means, and the data storage means,
When the light receiving unit receives infrared light including encoded data in the first power supply state, the data storage unit stores received light data related to the encoded data included in the received infrared light. A data receiving device characterized by.   When the light receiving means receives infrared light including encoded data in the first power supply state, the data storage means combines the encoded data included in the received infrared light with the decoding means. 2. The data receiving device according to claim 1, wherein the data receiving device stores the decoded data. When the light receiving means receives infrared light including encoded data in the first power supply state, the power supply control means performs power supply control for supplying power to the output processing means,
The data receiving device according to claim 2, wherein the supplied output processing means reads out the decoded data stored in the data storage means and performs output processing. When the power supply control unit performs power supply control for supplying power to the output processing unit, the data storage unit includes a detection unit that detects whether or not decoded data is stored.
The output processing means reads the decoded data from the data storage means when the detection means detects that the decoded data is stored in the data storage means. The data receiving device according to item.   5. The apparatus according to claim 1, further comprising a notification output unit configured to output a notification that the infrared light including the encoded data is received when the light receiving unit receives the infrared light including the encoded data. Data receiver for the term.

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