JP4110177B2 - Information communication equipment - Google Patents

Description

  The present invention relates to an information communication apparatus, for example.

  In recent years, portable electronic devices and the like tend to be miniaturized. Due to the downsizing of electronic devices, portability and storage are improved and usability is improving. In addition, the demand for various additional functions for electronic devices is increasing, and along with the development of technology, the performance of electronic devices is also increasing.

  Furthermore, in order to meet various needs for information devices in recent years, it has been devised to configure a system capable of controlling communication between electronic devices by connecting the electronic devices.

  When a system that can control communication between electronic devices is configured, it has the advantage that the functions can be expanded in various ways according to the user's needs. However, the operation procedure is complicated due to inconsistencies in the operability between electronic devices. There are issues such as

  In view of such a problem, an object of the present invention is to facilitate operation of a system configured by connecting a plurality of electronic devices and to improve operability.

  In order to achieve the above object, according to an information communication apparatus according to claim 1 of the present invention, an information communication network capable of transmitting information is configured by connecting to a plurality of electronic devices via a bus. An information communication apparatus capable of storing the storage unit storing its own operation state information and an electronic device in which a new electronic device is added to the information communication network or connected to the information communication network A communication means for transmitting self-information for identifying itself into the information communication network and a control means for adding the operation state information to the self-information when the information is newly deleted. To do.

  According to the control method for an information communication apparatus according to claim 7 of the present invention, an information communication network capable of transmitting information can be configured by connecting to a plurality of electronic devices via a bus. A method for controlling an information communication apparatus, comprising: a storage step of storing own operation state information; and a new electronic device added to the information communication network, or an electronic device connected to the information communication network A communication step of transmitting self-information for identifying the self into the information communication network when newly deleted; and a control step of adding the operation state information to the self-information. .

  As described above, according to the present invention, it is possible to grasp the current operating state of all devices connected via a network.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

(First embodiment)
FIG. 2 is a diagram illustrating an appearance of an imaging apparatus which is an electronic apparatus according to the present invention.

  The imaging device of FIG. 2 can communicate the recorder unit 1 and the camera unit 2 by radio waves or the like, and transmits a control signal for controlling the camera to the camera unit 2 from the recorder unit 1 which is an image receiving unit. A video signal, an audio signal, and the like are transmitted from the camera unit 2 to the recorder unit 1. In FIG. 2, the camera unit 2 includes a camera head unit 3 for photographing and a pan head 4 that controls the posture of the camera head unit 3. Reference numeral 11 denotes an operation switch having a function as an operation means capable of operating the camera unit.

  In this embodiment, in such a separate type imaging device in which the camera unit and the recorder unit are separated and wirelessly communicated between the two, if the communication between the camera unit and the recorder unit is impossible, the recorder unit An operation switch for controlling the installed camera unit enables operation control of other functions of the imaging apparatus.

  FIG. 3 is a schematic configuration diagram of the imaging apparatus according to the present embodiment.

  In FIG. 3, the imaging apparatus according to the present embodiment transmits and receives a predetermined signal wirelessly between the recorder unit 1 and the camera unit 2 as described above. The camera unit 2 further includes a camera head unit 3. And pan head 4.

  In the camera unit 2, the camera head unit 3 includes an imaging unit 20 and an image processing unit 19. The imaging unit 20 includes a lens unit such as a focus lens and a zoom lens, a diaphragm for adjusting the amount of light, and an imaging element that photoelectrically converts a light beam incident through the lens unit. In addition, the image processing unit 19 generates a luminance signal and a color signal from the imaging signal output from the imaging unit 20, and performs predetermined signal processing such as gamma correction and blanking processing, and is standardized such as NTSC. Convert to image signal.

  Moreover, the pan head 4 is comprised by each part demonstrated below. The antenna 7 receives a control signal for controlling the camera unit 2 transmitted from the recorder unit 1, and transmits an image signal and an audio signal to the recorder unit 1 side. Moreover, the identification signal which identifies whether communication is possible is always transmitted to the recorder part 1 side.

  The transmission / reception unit 5 demodulates the received control signal, transmits the demodulated signal to the control unit 15, and receives the image signal obtained by the image processing unit 19 and the audio signal obtained by a microphone (not shown). It is for modulating so that transmission is possible.

  That is, the antenna 7 and the transmission / reception unit 5 have functions as first transmission / reception means.

  The control unit 15 is configured by a CPU or the like and controls all of the control of the camera unit 2. For example, the control unit 15 issues an operation command to the servo mechanism 21 based on the control signal transmitted by the transmission / reception unit 5, and further the camera Various controls such as AF, AE, and zoom for the head unit 3 are executed.

  The control unit 15 is configured as a generation unit that periodically generates an identification signal for causing the recorder unit 1 to confirm the reception state of the identification signal from the camera unit 2 by a timer (not shown) and transmits the identification signal from the antenna 7. Has been.

  The servo mechanism 21 controls the posture (pan, tilt) of the camera head unit 3 based on a command from the control unit 15. The power supply unit 16 is for supplying power to each unit of the camera unit 2.

  Furthermore, the recorder unit 1 is configured by each unit described below.

  The control unit 14 includes a CPU and the like, and controls all the units of the recorder unit 1. The antenna 8 transmits a control signal for controlling the camera unit 2 and receives an identification signal, an image signal, and an audio signal from the camera unit 2.

  The transmission / reception unit 6 demodulates received signals such as an image signal and an audio signal, and transmits the demodulated signal to the control unit 14. The control signal obtained by the operation switch 11 can be transmitted by the antenna 8. It is for modulating as follows.

  That is, the antenna 8 and the transmission / reception unit 6 have a function as second transmission / reception means.

  Reference numeral 11 denotes an operation switch, which will be described in detail later, and is a switch to be controlled depending on the reception state of the identification signal transmitted from the camera unit 2.

  The television tuner 10 has a function as a television signal receiving unit, a function of receiving a television wave and modulating it to a signal that can be displayed on the LCD 9, and can receive a television broadcast by the recorder unit 1 alone. is there. Reference numeral 9 denotes an LCD, which is a monitor for displaying an image. The speaker 23 outputs sound based on the sound signal from the control unit 14. The LCD drive unit 18 displays a predetermined image on the LCD in response to a command from the control unit 14.

  The storage unit 22 has a function as a storage unit that stores a signal based on the signal received from the camera unit 2 and the signal received from the TV tuner 10 in a magnetic tape, an optical disk, a semiconductor memory, or the like.

  FIG. 5 is a front view and a side view showing details of the operation switch 11 which is a feature of the present embodiment.

  As shown in the figure, four tact switches 12 are arranged in a cross shape, and a predetermined signal such as a pulse signal is obtained by depressing the operation member 13 and contacting any one of the tact switches. ing.

  FIG. 4 is a diagram showing the assignment of operation input functions according to the reception state of the identification signal of the operation switch 11.

  When control of the camera unit 2 is possible (referred to herein as a camera operation mode), panning by pressing the operation member 13 in a desired operation direction with respect to the camera head 3 as shown in FIG. A tilt control signal can be generated.

  When the operation of the camera unit 2 is impossible, the operation is switched to an operation on the television signal obtained from the TV tuner 10 (referred to herein as a TV reception mode), and as shown in FIG. When the part is pressed, the channel of the television signal is switched, and when the upper and lower parts of the operation member 13 are pressed, the volume output from the speaker unit 23 can be adjusted.

  Such control is performed by the control unit 14 having a function as control means.

  FIG. 12 is a flowchart of the recorder unit 1 showing processing for switching between the camera operation mode and the television reception mode of the operation switch 11 as described above.

  First, in S1, when the identification signal from the camera unit 2 is not received by the antenna 8 due to reasons such as the camera unit 2 not operating or radio waves not reaching, in S2, the control unit 14 controls the camera unit 2 in S2. Is determined to be impossible, and the LCD drive unit 18 is instructed to display an image based on the television signal obtained from the television tuner. At the same time, the operation switch 11 is set to the television reception mode that enables the operation function described above as shown in FIG. Thus, by controlling the processing of the recorder unit 1, it is possible to adjust the volume of the audio signal relative to the television signal and switch the channel.

  In S6, when it is desired to end the operation, the power switch (not shown) is turned off and the operation of the OFF recorder unit 1 is ended.

  Next, when the identification signal from the camera unit 2 is received by the antenna 8 at S1 and the camera unit 2 is in the process of initializing the image signal at S3, the image signal cannot be transmitted. When the identification signal is received from the antenna 8, the control unit 14 sets the television reception mode in S4 as in S2.

  In S3, when the identification signal indicating that the image signal can be transmitted is received from the antenna 8, the control unit 14 determines that the operation control of the camera unit 2 is possible and sets the recorder unit 1 to the camera operation mode. The operation switch 11 is switched so as to enable the above-described operation function as shown in FIG. 4A, and further, the LCD 9 is switched so as to display the video transmitted from the camera unit 2.

  As described above, the operation switch 11 can generate a control signal for controlling the posture (pan, tilt) of the camera head by controlling the processing of the recorder unit 1.

  The image pickup apparatus according to the present embodiment sets the recorder unit 1 to the camera operation mode only when the camera unit 2 is capable of transmitting a video signal, so that the camera head unit of the camera unit 2 can be operated by operating the operation switch 11. 3 pan / tilt attitude control is possible.

  When the video signal cannot be received, the television signal obtained from the television tuner 10 is displayed on the LCD 9 by setting the recorder unit 1 in the television reception mode, and the operation switch 11 is used to switch the channel of the television signal or the speaker. 23 can be used to adjust the sound output from the audio signal 23.

  As described above, the operation device according to the present embodiment can operate different functions in the two operation modes of the recorder unit 1 described above.

(Second Embodiment)
FIG. 7 is a diagram illustrating an appearance of an imaging apparatus which is an electronic apparatus according to the present invention.

  In the imaging apparatus according to the present embodiment, the camera unit 2 and the recorder unit 1 are connected by a cable 37, both of which are physically connected by the connection unit of the camera unit 2 and the insertion unit 33 of the recorder unit 1 as shown in FIG. Connection is possible as shown in FIG. FIG. 7A shows a state where the camera unit 2 and the recorder unit 1 are physically separated.

  In the present embodiment, the operation function of the operation switch 11 shown in FIG. 7 is switched according to the physical connection state between the camera unit 2 and the recorder unit 1.

  FIG. 8 is a schematic configuration diagram of the imaging apparatus according to the present embodiment. Since the same reference numerals as those in FIG. 3 have the same configuration, the description thereof is omitted. The detection switch 34 is a switch that performs detection when the camera unit 2 and the recorder unit 1 are physically connected. In response to the switch detection signal, the control unit 14 switches the operation function of the operation switch.

  10A shows a state where the camera unit 2 and the recorder unit 1 are physically separated, and FIG. 10B shows a state where the camera unit 2 and the recorder unit 1 are physically connected. .

  From the state of FIG. 10 (a), the connecting part 36 on the camera part 2 side is fitted into the insertion part 33 of the recorder part 1, so that the physical connecting state of FIG. .

  In the physical connection state between the camera unit 2 and the recorder unit 1 in FIG. 10B, the protrusion 35 presses the detection switch 34. As a result, the detection switch having a function as a detection unit is turned on, and the control unit 14 determines that a physical connection state is established by this signal.

  FIG. 9 is a diagram illustrating assignment of operation functions of the operation switch 11 according to a mode when the imaging apparatus is in a predetermined mode. The operation switch 11 is the same as that shown in FIG. The assignment of the operation functions in FIG. 9 will be described with reference to the mode according to the flowchart of the operation process of the recorder unit 1 shown in FIG.

  First, in S21, when the camera unit 2 is not operating, the control unit 14 sets the recorder unit 2 in the reproduction mode, and in S24, the control unit 14 can reproduce the signal stored on the magnetic tape or the like by the storage unit. Then, an image is displayed on the LCD 9 based on the stored signal.

  When the recorder unit 1 is in such a playback mode, the operation switch 11 is assigned the function shown in FIG. When the upper part of the operation member 13 is pressed, a signal for reproducing an image on the LCD 9 is transmitted to the control unit 14, and when the lower part of the operation member 13 is pressed, a signal for stopping the reproduction of the image is transmitted to the control unit 14. Further, when the right part of the operation member 13 is pressed, a signal for executing fast-forwarding of the image is transmitted to the control unit 14, and when the left part is pressed, a signal for starting rewinding is transmitted to the control unit 14. At this time, the control unit 14 controls each component based on each signal.

  In S27, when all operations are finished, the power switch (not shown) is turned off to finish all operations.

  In S23, when the camera unit is operating and the control unit 14 recognizes that the camera unit 2 and the recorder unit 1 are separated from each other by a signal from the detection switch 34, in S25, the control unit 14 causes the operation switch 11 to operate. Is an operation function for generating a pan / tilt control signal by pressing the operation member 13 in accordance with a desired operation direction of the camera head 3 as shown in FIG. 9A. Switch.

  In S23, when the camera unit is in operation and the control unit 14 recognizes that the camera unit 2 and the recorder unit 1 are connected by a signal from the detection switch 34, the control unit 14 operates in S25. The switch 11 is set to the camera adjustment mode, and the function shown in FIG.

  When the upper portion of the operation member 13 is pressed, a signal for zoom control is transmitted to the control unit 14 so that the image becomes a wide angle according to the pressed time. When the lower part of the operation member 13 is pressed, a signal for zoom control is transmitted to the control unit 14 so that the image becomes telephoto.

  Further, when the right part of the operation member 13 is pressed, the camera head 3 is focused in accordance with the pressed time, and when the left part of the operation member 13 is pressed, the camera head is set according to the pressed time. 3 is transmitted to the control unit 14 so as to control the focus to a distance of 3. At this time, the control unit 14 controls each component based on each signal.

  As described above, the image pickup apparatus according to the present embodiment detects whether or not the camera unit 2 and the recorder unit 1 are connected, and switches the operation function of the operation switch 11 according to the detection result. A simple operation system can be obtained without using any operation switch.

(Third embodiment)
FIG. 1A shows an information communication system configured by connecting a plurality of electronic devices such as a plurality of image recording / playback apparatuses which are electronic devices in the present embodiment.

  In FIG. 1A, the camera unit 420 includes a RAM (not shown) capable of storing operation state information of the camera unit 420, and the other configuration is the same as that of the camera unit 2 shown in FIG. Pan / tilt operation control is possible. The monitor device 419 is for displaying an image captured by the camera unit 2 or an image reproduced by the image recording / reproducing device. Although this embodiment will be described with reference to the system shown in FIG. 1A, in addition to the devices connected to the system shown in FIG. 1A, the system may be expanded by connecting a plurality of devices. Is possible.

  Reference numerals 417, 418, and 421 denote image recording / playback apparatuses having functions equivalent to each other. The image signals captured by the camera unit 420 are recorded on a recording medium such as a magnetic tape or an optical disk, and the recorded images are monitored. It is possible to reproduce on the screen of 419. The monitor device 419 not only displays an image but also has a function as such an image recording / reproducing device.

  In the system shown in FIG. 1A, the connections between the devices are connected by an IEEE 1394 serial bus cable 422 (FIG. 1A) (IEEE: Institute of Electrical and Electronics Engineers). Each device has a function of relaying control signals and data signals input from the IEEE 1394 serial bus cable 422 to each device. Therefore, for example, the image recording / reproducing device 417 and the camera 420 connected to the end of the system are provided. Control signals or data signals can be communicated bidirectionally via the image recording / reproducing device 418, the image recording / reproducing device 421, and the monitor device 419.

  That is, the system of the present embodiment is equivalent to a communication system in which devices of a common IEEE 1394 serial bus are connected as shown in FIG.

  Here, features of the communication system based on IEEE1394 will be briefly described. In the IEEE1394 communication system, free connection forms such as daisy chain and node branching can be realized. In addition, even if the device is in a communicable state, the cable can be connected / disconnected, and each time the cable is connected / disconnected, the state of the connected device of the network is reset according to the IEEE 1394 standard, and each of the devices constituting the network A node number that is its own physical address is automatically assigned to the device. Each device is uniquely identified in the network by this node number.

  There are two modes of signal transfer on the IEEE 1394 serial bus: synchronous transfer and asynchronous transfer. In particular, the former is executed with priority over the latter, and real-time transfer is possible. In any transfer mode, data is transferred in packets.

  This packet is composed of a header part and a data part. The header portion includes information such as the node address of the transfer partner, its own node address, and the transfer data size. As a result, each node reads the header information of the transferred packet, and if it is for its own node address, reads the packet data and receives the data.

  FIG. 13 shows a front view of the image reproducing / recording apparatus as described above, and FIG. 17 shows a configuration diagram thereof. In FIG. 17, an I / F 431 is a window for exchanging signals with other devices via the IEEE 1394 serial bus 422. When the communication with the camera unit 420 is possible, the operation unit 425 is a switch for controlling the pan / tilt posture of the camera unit 420 and various operation switches for operating the configuration of each unit in the image reproduction / recording apparatus. Is a group.

  The start button 423 has a function as an operation unit capable of operating image reproduction / recording / dubbing according to the operation state of another device. As shown in FIG. 13, the indicator 424 displays which function (image playback / recording / dubbing) is currently operable by the start button 423, and the display unit 426 displays which function It displays whether the device is an operation target of its own device.

  When the image recording / reproducing devices 421, 417, and 418 are the device 1, device 2, and device 3, respectively, and when it is desired to reproduce the image recorded on the magnetic tape set in the device 2 by the device 1, the indicator 424 The “playback” lamp is turned on to allow the user to recognize it, and the display unit 426 displays “device 2” to be operated.

  The storage unit 432 is for storing an image signal on a magnetic tape or the like. In addition, the image processing unit 428 performs predetermined processing on the video signal transmitted via the IEEE 1394 serial bus 422, stores the video signal in an appropriate format in the storage unit 432, and stores the video signal in the CRT 433. Here, the CRT 433 is a monitor for displaying an image, and is installed only in the monitor device 419 in the present system.

  The ROM 429 is a storage medium that stores a program for causing the CPU 427 to execute various processing operations. Further, the unique ID address of the own device is stored in the ROM 429.

  The RAM 430 downloads the program stored in the ROM 429 and provides the work area to the overall control circuit 113 when it is read out. In addition, it is possible to write the operation state of its own device in the RAM 430 according to a command from the CPU 427. Further, the RAM 430 serves as a storage unit that stores operation state information of its own electronic device according to a command from the CPU 427.

  The CPU 427 executes various processing operations in accordance with a program downloaded to the RAM 430, and when a bus reset is executed, information such as a node number of the device is broadcast on the network. Broadcast transmission refers to transmission that is simultaneously sent to all nodes on the network without specifying a specific destination. Further, when a change occurs in the network configuration, the CPU 427 of one electronic device on the network exhibits a function as a bus reset unit and issues a bus reset command. Furthermore, the CPU 427 of each electronic device on the network broadcasts and transmits its own information and its operating state information to the entire network as a transmission means. Further, the CPU 427 has a function as control means for adding its own operation state information to the self information.

  Now, let us assume that communication is performed between a certain apparatus, for example, between the image reproduction / recording apparatus 417 and the monitor apparatus 419 on the system of FIG. It is assumed that the IEEE 1394 serial bus 422 is electrically disconnected for some reason. FIG. 14 is a flowchart showing an operation process in a communicating apparatus on the network in such a case. Here, in order to make it easy to understand the operation of this system, when communication is performed between the image reproduction recording device 417 and the monitor device 419 to reproduce an image, the IEEE 1394 serial bus 422 is disconnected. A specific explanation of the case is also given.

  In S101, first, when the IEEE 1394 serial bus 422 at a certain location is disconnected and a bus reset signal is transmitted, in S102, the CPU 427 of each device operates in communication before the IEEE 1394 serial bus 422 is disconnected. Is stored in the RAM 430 of each device. In the image reproduction / recording apparatus 417, the information on the image reproduction state and the communication destination (monitor apparatus 419) is stored in the RAM 430. Further, the monitor device 419 stores information on the image reproduction state and the communication destination (image recording / reproduction device 417) in the RAM 430.

  In S103, each device broadcasts information such as a node number in response to a bus reset signal, a route is determined, and a new network is configured.

  In S104, when the disconnected IEEE 1394 serial bus 422 is connected again, a bus reset signal is transmitted again. In s105, upon receiving the transmission of the bus reset signal, information such as a new node number is broadcasted as a packet from each device. The operation state before the connection of the bus cable 422 is disconnected to the self ID packet. Add information. An approximate data structure of such a packet is shown in FIG.

  In FIG. 18, the self-ID packet transmitted when the bus is reset is stored in the RAM 504 in information such as the node number 501, the type of device 502, the terminal connection status (whether it is the end of the system) 503, and the like. The stored operation state information (information of the communication partner and the operation state of the own device) is added. For example, in the transmission from the image reproduction / recording device 417, the information indicating that the image is being reproduced and the communication destination (monitor device 419) is added to the packet, and the image reproduction state is obtained from the monitor device 419. And information of the communication destination (image recording / reproducing apparatus 417) of the user is added.

  In S106, the self ID packet shown in FIG. 18 is broadcast from each device, and when each device finds a packet having communication destination information from among the devices, the destination of the packet is the connection of the bus cable 422. It is recognized that it is the communication destination before the time expires. For example, the image recording / reproducing device 417 communicates with the monitor device 419 and determines that the reproducing operation is performed, and the monitor device also recognizes that the image recording / reproducing device 417 communicates with the image recording / reproducing device 417 to execute the reproducing operation. .

  In S107, the operation is resumed from the communication immediately before the connection of the bus cable is disconnected in the devices (for example, the image recording / reproducing device 417 and the monitor device 419) in which the communication has been performed.

  As described above, according to the present embodiment, for example, when a bus reset is transmitted when the cable is disconnected, the operation state information immediately before that is saved in the RAM in each device. When the cable is connected again, the bus reset occurs again, but the operation state information saved in the RAM at that time is added to the self ID packet of each device, and the packet is broadcast. The communication destination before the connection is disconnected can be confirmed, and the communication can be resumed from the state immediately before the cable is disconnected.

  In S102 described above, when the bus reset signal is transmitted on the network as the operation information of each device, the CPU 427 stores the operation status information of its own device in the RAM 430. The operation state information may always be updated and stored in the RAM 430 at the timing (predetermined interval).

  The flowchart at this time is shown in FIG. In S101a, the CPU 427 updates the operation state information at a predetermined timing and stores it in the RAM 430. When a bus reset is transmitted in S102a, the update is stopped. The rest is the same as the flowchart of FIG. 14, and a description thereof will be omitted.

(Fourth embodiment)
In this embodiment, when data transfer is not performed on the bus, a bus reset is generated at a predetermined timing, and accordingly, operation state information of each device is added to a self-ID packet transmitted from each device. Thus, the operation information of each device is confirmed, and an operation corresponding to the operation state is performed on each device.

  The configuration of this system is the same as that shown in FIG. 1 (a). Here, the image recording / reproducing apparatus serves as an operating device serving as host means, and the image recording / reproducing apparatuses 417, 418 are used as VTR (A). , VTR (B). In addition, the operating devices, VTR (A) and VTR (B) have the same configuration as in FIG.

  FIG. 11 shows a flowchart of the operation process of the operating device that functions as a route.

  In S201, when data is not transferred on the network, in S202, the CPU 427 of the operating device functioning as a route transmits a bus reset signal at a predetermined timing (predetermined interval) according to a certain protocol. In S203, the operating device obtains the respective operation state information added to the self ID packet by obtaining the broadcast self ID packet (FIG. 18) of each device. Information on the operating state of this embodiment includes whether or not a tape is inserted, whether or not a tape is inserted, and whether or not the camera unit 420 is operating.

  If the operating device recognizes that there is a tape in either the VTR (A) or VTR (B) in S204, the location of the tape is confirmed in S205. If both are present, the process proceeds to S206, and it is checked whether or not the tape is prohibited from recording. If one of the VTR (A) and VTR (B) is prohibited from recording, the start switch 423 enters the dubbing mode and the “dubbing” indicator 424 lights up.

  When both the VTR (A) and VTR (B) are prohibited from recording on the tape, a playback mode for playing back the VTR inserted later on the monitor device 419 is entered. At this time, “reproduction” of the indicator 424 is lit, and the display unit 426 displays the device of the VTR (for example, VTR (A)) to be reproduced.

  In S205, if there is only one of VTR (A) and VTR (B), the process proceeds to S207 and it is confirmed whether or not the recording of the tape is prohibited. When the recording is prohibited, the start switch 423 enters a reproduction mode for reproducing the VTR on the monitor device 419. At this time, “reproduction” of the indicator 424 is turned on, and the VTR device to be reproduced is displayed on the display unit 426.

  If it is determined in step S207 that the inserted tape is not prohibited from recording, the process advances to step S208 to check whether the camera unit 420 is operating. If not, the start switch 423 enters a playback mode for playing back the VTR to the monitor device 419. At this time, “reproduction” of the indicator 424 is turned on, and the VTR device to be reproduced is displayed on the display unit 426.

  When the camera unit 420 is operating, the CPU 427 of the operating device issues a video signal transfer request from the camera unit 420, and the start switch 423 enters a recording mode for recording on a tape. At this time, “recording” of the indicator 424 is turned on, and the VTR apparatus in which the tape to be recorded is inserted is displayed on the display unit.

  In each of S209, S210, S211, and S212, after each mode is switched, each process is executed when the start button 423 is pressed in S213.

  For example, when the playback command for the tape inserted in the VTR (A) is executed by the start button 423, as shown in FIG. The huge M number is sent to reproduce and transfer to the monitor device 419, and a control signal is sent to the monitor device 419 to receive the output signal of the VTR (A) and display the video on the monitor. As a result, the image is reproduced.

  Further, for example, when a dubbing command for recording the recording content of the tape inserted in the VTR (A) on the tape inserted in the VTR (B) is executed by the start button 423, as shown in FIG. In addition, the operating device requests the VTR (A) to transfer the recording signal of the tape to the VTR (B), and further sends a control signal for recording to the inserted tape to the VTR (B). . As a result, the image is reproduced.

  As described above, the root device performs a bus reset at a predetermined timing when data transfer is not performed, and adds the operation state information of each device to the self-ID packet of each device transmitted by the bus reset. Thus, it is possible to grasp the status of the entire system. In addition, an operation system in a complex system can be simplified by automatically assigning an appropriate operation function to the start button based on the operation state information.

(A) is a figure which shows the information communication system of this invention. (B) is a figure which shows the structure equivalent to the information communication system of this invention. 1 is an external view of an imaging apparatus according to the present invention. 1 is a schematic configuration diagram of an imaging apparatus of the present invention. The figure which shows the allocation of the function of the operation switch according to a mode. The block diagram of an operation switch. 6 is a flowchart of operation processing of the imaging apparatus. 1 is an external view of an imaging apparatus according to the present invention. 1 is a schematic configuration diagram of an imaging apparatus of the present invention. The figure which shows the allocation of the function of the operation switch according to a mode. (A) is a figure which shows the state which the camera part and the recorder part physically separated in the connection location. (B) is a figure which shows the state which the camera part and the recorder part physically connected in the connection location. The operation | movement process flowchart of the information communication system of this invention. 3 is an operation processing flowchart of the imaging apparatus according to the present invention. The front view of an image recording / reproducing apparatus. The operation | movement process flowchart of the information communication system of this invention. The flowchart explaining the mode of the control switching based on the information regarding a tape. The flowchart explaining the mode of the control switching based on the information regarding a tape. 1 is a schematic configuration diagram of an image recording / reproducing apparatus. The figure which shows the data structure of a packet in the information communication system of this invention. The operation | movement process flowchart of the information communication system of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Recorder part 2 Camera part 3 Camera head part 4 Pan head 5 Transmission / reception part 6 Transmission / reception part 7 Antenna 8 Antenna 9 LCD
DESCRIPTION OF SYMBOLS 10 Television tuner 11 Operation switch 14 Control part 15 Control part 22 Storage part 33 Insertion part 34 Detection switch 417 Image recording / reproducing apparatus 418 Image recording / reproducing apparatus 421 Image recording / reproducing apparatus 419 Monitor apparatus 420 Camera part 422 IEEE1394 serial bus 423 Start button 427 CPU
429 ROM
430 RAM
431 I / F
432 Storage unit 433 CR

Claims (7)

An information communication device capable of configuring an information communication network capable of transmitting information by connecting to a plurality of electronic devices via a bus,
Storage means for storing the operation state information of itself;
When a new electronic device is added to the information communication network or an electronic device connected to the information communication network is newly deleted, self-information for identifying itself is stored in the information communication network. A communication means for transmitting to
An information communication apparatus comprising: control means for adding the operation state information to the self information.   A bus reset that issues a command to reconstruct the information communication network when a new electronic device is added to the information communication network or an electronic device connected to the information communication network is newly deleted The information communication apparatus according to claim 1, further comprising means.   The information communication apparatus according to claim 1, wherein the storage unit updates the operation state information at a predetermined interval. 3. The information communication apparatus according to claim 2, wherein the storage unit updates the operation state information when the bus reset unit transmits a restructuring command. The information communication apparatus according to claim 1, wherein the communication unit further transmits the self-information into the information communication network at a predetermined timing when communication is not performed.   6. The information communication apparatus according to claim 5, wherein the communication unit transmits the self information to the information communication network in response to the bus reset unit transmitting a reconfiguration command. An information communication device control method capable of configuring an information communication network capable of transmitting information by connecting to a plurality of electronic devices via a bus,
A storage step for storing the operation state information of the device;
When a new electronic device is added to the information communication network or an electronic device connected to the information communication network is newly deleted, self-information for identifying itself is stored in the information communication network. A communication step to send to
And a control step of adding the operation state information to the self-information.

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