JP4752151B2 - Commander device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a commander device that transmits a usage history stored in an electronic device to the outside.
[0002]
[Prior art]
In the process of designing a product, a company is trying to design a product that is more demanded by the user, such as how the user uses it and what the user uses frequently. We collect information on whether we want it every day. The obtained information is utilized in product design.
[0003]
Companies have collected user requests through questionnaire postcards bundled with devices and recently through questionnaire surveys on the Web.
[0004]
[Problems to be solved by the invention]
However, this has a problem that only the opinions of only the user who wrote the postcard or the user who submitted the questionnaire on the Web can be extracted. In other words, there is a possibility that only a part of unique opinions such as a user who wrote a postcard and a user who submitted a questionnaire on the Web are taken up, although the user's opinion is widely taken up.
[0005]
Accordingly, an object of the present invention is to provide a commander device that can collect information related to user preferences without being conscious of the user.
[0006]
[Means for Solving the Problems]
According to the first aspect of the present invention, in the commander device for remotely controlling the controlled device, the first memory means for storing the usage status, the second memory means for storing the program and rewriting the program, and the use A commander device comprising a communication means for transmitting a history of status to an external server and a control means for controlling based on a program, and transmitting a history of usage status to the server when the program is updated .
[0007]
Since usage history can be sent to the outside, companies can collect usage history and determine user preferences based on user hobbies, thoughts, behavior patterns, etc., and reflect them in products be able to.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Note that components having the same function throughout the drawings are denoted by the same reference numerals to avoid duplication of description. FIG. 1 shows an embodiment using a remote commander (hereinafter referred to as “remote controller”) 1 to which the present invention is applied. The remote controller 1 includes a liquid crystal screen 11 including a touch panel and physical remote control keys. When the user presses a physical remote control key or touches a button displayed on the liquid crystal screen 11, a remote control signal corresponding to the content is transmitted from the remote control 1. When receiving a remote control signal transmitted from the remote controller 1, the AV (Audio and Visual) amplifier 2 performs an operation according to the content.
[0009]
Here, the signal used in the remote controller 1 includes, for example, a SIRCS (Standard Code for Infrared Remote Control System) signal capable of one-way communication from the remote controller 1 to the AV amplifier 2 and between the remote controller 1 and the AV amplifier 2. For example, there are two types of control-A1 signals that can be used for bidirectional communication.
[0010]
An example of the transmission waveform of the SIRCS signal, which is the format of the remote control signal for one-way communication, is shown in FIG. The transmission waveform shown in FIG. 2 is an example of a 12-bit format. As shown in FIG. 2A, one frame is from the guide pulse to the next guide pulse. The guide pulse is a determination signal that is placed in advance to define the start of the serial remote control signal. Following this guide pulse, 2 ⁰ , 2 ¹ ,..., 2 ¹⁰ , 2 ¹¹ and 12-bit data are transmitted. Seven bits on the LSB side of the 12-bit data is a data code, which is a code for controlling a necessary operation function in a predetermined product category. The 5 bits on the MSB side are a category code, which is a code assigned to each product category targeted for the remote control system.
[0011]
As shown in FIG. 2B, the guide pulse time tg is 2.4 msec, and the data bit off time toff is 0.6 msec. Since the data bit on time ton1 when it is “1” is 1.2 msec, the data cycle T1 when it is “1” is 1.8 msec. Since the data bit on time ton0 when it becomes “0” is 0.6 msec, the data cycle T1 when it becomes “0” is 1.2 msec. The output frame period tf is 45.0 msec.
[0012]
The SIRCS signal defines a 15-bit format and a 20-bit format in addition to the 12-bit format shown in FIG. In the 15-bit format, 7 bits on the LSB side are data codes, and 8 bits on the MSB side are category codes. In the 20-bit format, 7 bits on the LSB side are data codes, and 13 bits on the MSB side are category codes.
[0013]
Next, FIG. 3 shows an example of a transmission waveform of a Control-A1 signal which is a format of a remote control signal for bidirectional communication. This Control-A1 signal uses a 40 kHz SIRCS signal data transmission format for communication from the remote control 1 to the AV amplifier 2, and uses a 455 kHz high-speed remote control format for communication from the AV amplifier 2 to the remote control 1. Two-way communication is performed.
[0014]
FIG. 3A and FIG. 3B show the basic bit configuration of a 455 kHz high-speed remote control format when transmitting from the AV amplifier 2 to the remote controller 1. The start bit shown in FIG. 3A is a pulse indicating the start of a signal. The format is 1-byte data indicating the classification of data. In this format, it is defined that data for SIRCS conversion signal, Audio 2-WAY REMOTE (CONTORL A1), Audio 2-WAY REMOTE (Audio System), and Audio MULTI ROOM CONTORL is transmitted as continuous data. . The data is composed of N bytes of data and has a maximum of 30 bytes. Parity is a value obtained by exclusive-ORing each data in byte units from a format indicating the classification of data. The end bit is a pulse for defining the last bit.
[0015]
The start bit shown in FIG. 3B is 237.4 μsec, and the end bit is 44 μsec. The other bits that are “0” are 131.9 μsec, and the bits that are “1” are 184.6 μsec.
[0016]
FIG. 3C shows a 40 kHz remote control signal format when transmitting from the remote control 1 to the AV amplifier 2. Each of the three start words has a frame period of 45 msec and each of the n data words has a frame period of 22.5 msec. In order to improve the transmission speed, only the data word has a frame period of 22.5 msec. The check word is a value obtained by calculating an exclusive OR between the values of the first 8 bits of each data word and further calculating an exclusive OR with the total number of data words.
[0017]
In this way, by applying the Control-A1 signal, the remote controller 1 can receive an infrared signal of 455 kHz, and the AV amplifier 2 can receive an infrared signal of 40 kHz.
[0018]
Returning to FIG. 1, a request signal of 40 kHz Control-A1 signal format is transmitted from the remote controller 1 to the AV amplifier 2. From the AV amplifier 2, equalizer setting information set in the AV amplifier 2 as an answer signal responding to the received request signal, speaker setting information, the type of sound field mode used and the number of times of each, etc. Is transmitted to the remote controller 1 in the 455 kHz Control-A1 signal format. For example, various modes such as a rock concert mode, a classic concert mode, an outdoor live mode, and a movie theater mode are prepared for the sound field mode.
[0019]
When receiving data transmitted from the AV amplifier 2, the remote controller 1 displays the content on the liquid crystal screen 11. This AV amplifier 2 is provided with a terminal for Control-A1 signal, and can be connected to a CD changer 3 or an MD player 4 provided with a terminal for Control-A1 signal. It is possible to send and receive data. The CD changer 3 holds, for example, 400 discs, and can select and play one disc from among them.
[0020]
The flow of signals in the system connected as shown in FIG. 1 will be described with reference to the flowchart of FIG.
[0021]
In step S <b> 1, a request signal is transmitted from the remote controller 1 to the AV amplifier 1. In this example, a request signal for requesting the title of the currently set disc from among 400 discs held by the CD changer 3 or the title of the currently played disc is transmitted from the remote control 1 to the AV amplifier 2. . As described above, the request signal transmitted from the remote controller 1 to the AV amplifier 2 is an infrared signal converted into a 40 kHz Control-A1 signal format.
[0022]
In step S2, the AV amplifier 2 receives the request signal. The AV amplifier 2 determines to which device the received request signal is a transmitted request signal.
[0023]
In step S3, the request signal is transmitted from the AV amplifier 2 to the device to which the request signal has been sent. In this example, a request signal is transmitted from the AV amplifier 2 to the CD changer 3 via a wired A1 cable.
[0024]
In step S4, the CD changer 3 receives the request signal. In the CD changer 3, the title of the currently set disc or the title of the currently played disc is captured from the 400 discs in response to the request signal.
[0025]
In step S5, the captured disc title is transmitted as an answer signal from the CD changer 3 to the AV amplifier 2, and the received answer signal is transmitted from the AV amplifier 2 to the remote controller 1. At this time, the answer signal transmitted from the AV amplifier 2 to the remote controller 1 is an infrared signal converted into a 455 kHz Control-A1 signal format.
[0026]
In step S6, the remote controller 1 receives an answer signal. The remote controller 1 displays the content of the received answer signal on the liquid crystal screen 11.
[0027]
In the flowchart shown in FIG. 4, the request signal is transmitted from the remote controller 1 to the CD changer 3, but the same method can be used even if the request signal is transmitted to the MD player 4. For example, when a request signal for requesting the title of the disc currently set in the MD player 4 or the title of the disc currently being played is transmitted from the remote controller 1, the title of the disc currently set in the MD player 4 Alternatively, the title of the currently played disc is transmitted to the remote controller 1 as an answer signal.
[0028]
Here, a block diagram of an example of the internal configuration of the remote controller 1 is shown in FIG. The internal configuration of the remote controller 1 is mainly composed of a main CPU (Central Processing Unit) 21, a sub CPU 22, a ROM (Read Only Memory) 23, and an SRAM (Static Random Access Memory) 24. In particular, the main CPU 21 is a control unit that is the center of the remote controller 1, the sub CPU 22 is connected to the main CPU 21 by a so-called URAT (Universal Asynchronous Receiver Transmitter), and the ROM 23 and the SRAM 24 are a 16-bit address bus / data bus. Is connected to the main CPU 21.
[0029]
An LCD (Liquid Crystal Display) controller 25 is connected to the main CPU 21 via a 16-bit address bus / data bus and four port control lines. A VRAM (Video Random Access Memory) 26 is coupled to the LCD controller 25 via an 8-bit data bus. The VRAM 26 stores display data to be displayed on the liquid crystal screen 11 constituted by an LCD. The LCD controller 25 exchanges data with the main CPU 21 and performs display control of the liquid crystal screen 11. At this time, display control of the liquid crystal screen 11 is performed by parallel 4-bit data supplied from the LCD controller 25.
[0030]
The touch panel controller 28 is connected to the main CPU 21 via five UARTs. The touch panel controller 28 is supplied with the position coordinate data from the touch panel 29 when an object touches and reacts with the touch panel 29. The position coordinate data is supplied from the touch panel controller 28 to the main CPU 21 as 7-bit data. The main CPU 21 detects where on the touch panel 29 is pressed based on the supplied 7-bit data. The touch panel 29 is provided on the liquid crystal screen 11.
[0031]
The backlight 30 is provided on the back side of the liquid crystal screen 11, and its brightness is controlled from the main CPU 21 by one port control line.
[0032]
The main CPU 21 has a function of communicating with an external device (such as a PC (Personal Computer)) via the RS-232C driver circuit 31 and the stereo mini plug 32, and can send and receive commands to and from the outside through the path.
[0033]
The sub CPU 22 is controlled by the main CPU 21 and drives a connected LED (Light Emitting Diode) 33 to output an infrared signal converted into a 40 kHz Control-A1 signal format as a request signal. The sub CPU 22 has a function of receiving a command from the ROM, RAM, and main CPU 21 and outputting a remote control chip set code. This remote control chipset code output function is a function of outputting about 60 infrared remote control signal formats of various companies.
[0034]
The sub CPU 22 also has a learning function. The sub CPU 22 can receive a command from the main CPU 21 and learn a remote control code. At this time, an infrared remote control code output from another remote controller is received by the light receiving unit 34 connected to the sub CPU 22. When the learning is successful in the sub CPU 22, the content of the received remote control code is converted into data, supplied to the main CPU 21, and stored in the SRAM 24 connected to the main CPU 21.
[0035]
When it is desired to transmit the learned remote control code, the corresponding data is transmitted from the main CPU 21 to the sub CPU 22 to drive the LED 33 connected to the sub CPU 22, thereby outputting the learned remote control code.
[0036]
The light receiving unit 35 connected to the main CPU 21 receives an infrared signal converted from the 455 kHz Control-A1 signal format transmitted from the AV amplifier 2 as an answer signal. The received 455 kHz infrared signal is supplied to the main CPU 21.
[0037]
The input detection unit 36 is connected to the main CPU 21 and detects that a physical button provided on the remote controller 1 has been pressed. When it is detected that the button has been pressed, the main CPU 21 determines the content.
[0038]
The general I / O input detection unit 37 is connected to the main CPU 21 and detects contents such as that the stereo mini plug is connected to the stereo mini plug 32 of the remote controller 1 or that the voltage level of the power source has decreased. Can do.
[0039]
The ROM 23 stores a program executed by the main CPU 21. Further, since the ROM 23 is composed of a flash memory, the stored contents, that is, the program can be rewritten freely.
[0040]
In the SRAM 24, for example, a memory area necessary for executing a program, setting information of a remote control manufacturer and a device manufacturer, model information of the main body, a learned remote control code, and a history of user usage (hereinafter referred to as “log”) Etc.) are stored. Since this log data records the actual usage by the user, the user's preference can be understood by looking at the log data.
[0041]
In this log data, as a general usage status log, the time when the liquid crystal screen 11 is on, the time when the backlight 30 is on, the number of remote control code transmissions, and the like are stored. As general data, learned remote control signal data, remote control operation information such as which channel has been pressed and how many times, and the like are stored. In addition, as a usage log specialized for the function of the AV amplifier 2, the type and number of sound field modes used in the AV amplifier 2 selected by the user from the remote controller 1, and the equalizer set by the user Customized data such as setting information is stored.
[0042]
The main CPU 21 holds an MPU (Micro Processing Unit) and ROM and RAM therein. During normal operation, the program stored in the ROM 23 provided outside is operating, but there is a period during which the program stored in the ROM provided inside operates. As an example, there is no input from the outside for a certain period of time when the remote controller 1 is not operated during startup at power-on (immediately shifts to a program stored in the external ROM 23), and a microcomputer for reducing power consumption When the program enters the sleep mode, the program stored in the internal ROM operates when the ROM 23 enters the rewrite mode.
[0043]
Although not shown in FIG. 5, a backup power supply is secured so that power is supplied even if the power supply voltage of the remote controller 1 is disconnected. As an example, this backup power source is composed of an electrolytic capacitor, and is provided in the SRAM 24 in order to hold the contents. The content can be held for at least 10 minutes.
[0044]
Here, an example of rewriting of the program stored in the ROM 23 will be described with reference to a flowchart shown in FIG. 6 and a connection schematic diagram shown in FIG.
[0045]
In step S11, application software (hereinafter simply referred to as “software”) for rewriting the program stored in the ROM 23 of the remote controller 1 is activated by the PC 41.
[0046]
In step S12, when “acquire remote control program” control is selected in the activated software, the software accesses, for example, the server 43 in which the remote control program is stored in order to acquire the remote control program. To do. Then, a program to be applied to the ROM 23 of the remote controller 1 is downloaded from among a plurality of programs prepared in the server 43. When accessing the server 43 via the network 42, a normal public line may be used, or a CATV (Cable Television) network service or a cellular phone network service may be used. Of course, any of dedicated lines, terrestrial waves, and satellite waves may be used. As a communication method, any protocol may be used as long as it can access the server 43. For example, peer-to-peer (PtoP: Peer to Peer) that directly connects many individuals and shares information may be applied. . In this example, the server 43 that stores the remote control program is accessed. However, the server 43 may be a server prepared by a company, or stores the program applied to the ROM 23. Any area may be used as long as it is an area, and the area is not limited to a specific server 43. For example, it may be an area of a third party storing a plurality of programs of a plurality of manufacturers, a so-called home page.
[0047]
In step S13, the PC 41 and the remote controller 1 are connected by RS-232C. In the remote controller 1, the general I / O input detection unit 37 detects that the RS-232C is connected to the stereo mini plug 32. When it is detected that the RS-232C is connected, the program shifts to a rewrite mode in which the program in the ROM 23 on the remote control 1 side is rewritten. That is, the program stored in the main CPU 21 is executed. And the remote control 1 will be in the state which waits for the command sent via RS-232C from PC41.
[0048]
In step S14, the program in the ROM 23 is rewritten from the software on the PC 41.
[0049]
In step S15, in order to rewrite the program, first, initial communication is performed between the PC 41 and the remote controller 1, and the communication baud rate is adjusted and set.
[0050]
In step S <b> 16, an inquiry screen as to whether the user log data stored in the SRAM 24 may be uploaded to the server 43 is displayed on the screen of the PC 41. At this time, the contents of the log data of the user and the explanation thereof are also displayed on the screen of the PC 41. If the user determines that the log data may be uploaded, the control moves to step S17, and if it is determined not to upload, the control moves to step S19.
[0051]
In step S <b> 17, the user's log data stored in the SRAM 24 is requested from the PC 41 to the main CPU 21. The requested log data is transmitted from the remote control 1 to the PC 41 via RS-232C.
[0052]
In step S18, the received log data is uploaded from the PC 41 to the connected server 43.
[0053]
In step S19, the program shifts to a rewrite mode in which the program in the ROM 23 is rewritten. First, the contents of the ROM 23 are erased. Then, a new program downloaded in advance from the PC 41 to the main CPU 21 is transmitted between the PC 41 and the main CPU 21 while handshaking. The transmitted new program is written into the ROM 23 by the program recorded in the ROM inside the main CPU 21. When a new program is written in the ROM 23, the operation ends.
[0054]
Thus, the log data uploaded to the server 43 is collected by the company. As described above, since the log data records the actual use situation of the user, the company creates a database of the collected log data so that the user's hobbies, thoughts, behavior patterns, etc. The preference can be determined and reflected in the product.
[0055]
If the AV amplifier 2 has a memory having the same function as the ROM 23, the PC 41 downloads a new program applied to the AV amplifier 2 from the server 43 via the network 42, and downloads the memory of the AV amplifier 2. Can be rewritten to a new program. In this way, the user can also acquire a new sound field mode.
[0056]
If the AV amplifier 2 has a memory having the same function as that of the SRAM 24, it is connected to the PC 41 via the RS-232C as in the remote controller 1 as shown in FIG. The log data of the AV amplifier 2 can be uploaded. At this time, as the log data stored in the memory of the AV amplifier 2, the type of the sound field mode used and the number of times of each are stored. Thus, popular sound field modes can be examined.
[0057]
Further, for example, when a new program is completed, the user who uploaded the log data to the server 43 may be informed by e-mail, mail, telephone, FAX or the like.
[0058]
In this embodiment, the remote controller 1 uploads log data stored in the SRAM 24 from the PC 41 to the server 43 via the network 42. However, the present invention is not limited to this, and the log data in the SRAM 24 of the remote controller 1 can be uploaded. Any route may be used, and log data may be uploaded directly from the remote controller 1 to the server 43.
[0059]
In this embodiment, the cordless remote controller 1 is used, but there is no problem even if the remote controller 1 with a cord is used.
[0060]
【The invention's effect】
According to the present invention, since the company can collect the log data actually used by the user, the collected log data can be analyzed and analyzed, and can be utilized in the product as information in the next design. . For example, the sound field mode that is not often heard is to reduce the scale of the design or to publish the popularity ranking of the sound field mode on the Web, etc. to provide the user with the enjoyment of new products Can do.
[0061]
According to the present invention, by collecting learned remote control data, it is possible to collect new remote control codes and the like that were not in the company database. The collected new remote control code is taken into a new product and can be provided as a product more convenient for the user.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a system to which the present invention can be applied.
FIG. 2 is a timing chart of an example of a remote control signal format to which the present invention is applied.
FIG. 3 is a timing chart of an example of a remote control signal format to which the present invention is applied.
FIG. 4 is a flowchart for explaining an example of signal transmission / reception according to the present invention;
FIG. 5 is a lock diagram of a remote control to which the present invention is applied.
FIG. 6 is a flowchart for explaining log data upload according to the present invention;
FIG. 7 is a schematic view for explaining uploading of log data according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Remote control, 2 ... AV amplifier, 3 ... CD changer, 4 ... MD player, 11 ... Liquid crystal screen, 21 ... Main CPU, 22 ... Sub CPU, 23. ..ROM, 24 ... SRAM, 41 ... PC, 42 ... network, 43 ... server

Claims (4)

In the commander device that remotely controls the controlled device,
First memory means for storing a usage situation ;
Second memory means for storing the program and capable of rewriting the program;
A communication means for transmitting the usage history to an external server;
Control means for controlling based on the program ,
A commander device that transmits the usage history to the server when the program is updated . The commander device according to claim 1, wherein the usage history includes a signal format used when data is transmitted to and received from the controlled device and a number of times the signal format is used. 2. The commander according to claim 1, wherein the usage history is composed of the type of the sound field mode used and the number of times the sound field mode is used in the controlled device. apparatus. The commander device according to claim 1, wherein the usage history is a signal format transmitted to and received from the learned controlled device.

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