JP3783318B2 - Communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a technical field of a wireless communication apparatus that performs communication according to a predetermined spread code by a spread spectrum method.
[0002]
[Prior art]
  Conventionally, in a communication system using the spread spectrum communication method, a communication method based on a frequency hopping method (hereinafter referred to as FH method) is used in order to effectively use a frequency and improve confidentiality. The FH system performs spreading by hopping a carrier according to a rule predetermined by a spreading code sequence. A transmission / reception apparatus in a conventional bidirectional communication system using a spread spectrum communication system based on the FH system is configured, for example, as shown in FIG.
[0003]
  First, when transmission is performed, a signal with a random frequency is output from the frequency synthesizer 206 in accordance with the spreading code sequence output from the spreading code sequence generator 205. On the other hand, the primary modulation signal is input to the transmission data input terminal 220, and the output frequency of the primary modulation signal is determined by the up-converter 203 based on the output from the frequency synthesizer 206. The transmission data frequency-converted by the up-converter 203 is amplified by the amplifier 208, and then transmitted from the antenna 211 via the duplexer 210.
[0004]
  Next, when reception is performed, the signal received by the antenna 211 is separated from the transmission wave by the duplexer 210, amplified by the amplifier 209, and then input to the down converter 207. Then, the frequency is converted by the down converter 207 based on the signal designating the frequency from the frequency synthesizer 206, and demodulated by the demodulator 212 to be received data. The received data is output to a data operation circuit (not shown) and also output to the synchronization circuit 204. The synchronization circuit 204 detects the phase of the hopping frequency from the received signal, and outputs the synchronization signal from the synchronization circuit 204 to the spreading code sequence generator 5. The spreading code sequence generator 205 outputs a spreading code sequence in accordance with the input synchronization signal. The spreading code sequence output from the spreading code sequence generator 205 is supplied to the frequency synthesizer 206, and the frequency synthesizer 206 is input. A random frequency output is generated according to the spread code sequence.
[0005]
  The down converter 207 despreads the received signal by multiplying the received signal by the output from the frequency synthesizer 206. The despread signal despread in the down converter 207 is demodulated by the demodulator 212, and the demodulated reception data is output from the reception data output terminal 221.
[0006]
  Two-way communication is performed by simultaneously operating the transmission unit and the reception unit as described above.
[0007]
  In addition, the random frequency means that the spreading code that is output every time a synchronization signal is input from the spreading code generator 205 changes randomly.ThisThis transmission code sequence (frequency hopping pattern) is shared between a pair of communication devices, and transmission / reception is performed.
[0008]
  As a specific example of an apparatus using such a communication method, an apparatus having both a facsimile function and a printer function is used as a parent machine, and a personal computer is used.TA data terminal such as the above is used as a slave unit, and the communication method is used for communication between the master unit and the slave unit.
[0009]
  According to this device, the personal computerTThe master unit can be used as a printer by printing out the data transmitted from the slave unit such as the master unit. When facsimile data is transmitted from the outside line, the data is transmitted to the master unit. Can be used as a facsimile machine.
[0010]
[Problems to be solved by the invention]
  However, in the conventional apparatus, the parent machine is a personal computer.TIf the facsimile data is transmitted from the outside line while receiving data from the slave unit and performing the print output, the printer unit is already in use. The facsimile machine of this type was in a standby state, and an error occurred due to a time-out, and normal reception could not be performed by the master machine.
[0011]
    In particular, when spread spectrum digital communication such as the frequency hopping method as described above is performed between the master unit and the slave unit, the frequency used for communication and the switching timing should be matched with each other. In the conventional method, it is necessary to prioritize communication processing between the parent device and the child device.
[0012]
  The present invention has been made in view of the above-described problems. In a communication apparatus that has at least a facsimile function and a printer function and performs spectrum spread digital communication, facsimile transmission from an outside line occurred during print output by the communication. Even in such a case, it is an object to provide a communication apparatus that can normally receive the facsimile transmission data and can also perform print output normally.
[0013]
[0014]
[0015]
[0016]
[0017]
[0018]
[0019]
[0020]
[0021]
[0022]
[0023]
[0024]
[Means for Solving the Problems]
  Claim1The communication device described in (1) includes: a master unit connected to at least one external communication line; and a slave unit that generates at least one non-voice data connected to the radio communication line by the frequency hopping method with the master unit. The master device includes an external transmission / reception unit that transmits / receives data through the external communication line, a data type determination unit that determines a type of data to be transmitted / received, and data that is determined by the data type determination unit Wirelessly transmits and receives at least non-speech data by frequency hopping between the data conversion means for converting data into a format that can be handled either on the external communication line side or on the device internal side according to the type External image forming data which is image forming data received by the base side wireless transmitting / receiving means and the external line transmitting / receiving means via the external communication line, or Image forming means for visualizing at least one of slave image forming data, which is image forming data transmitted from a slave and received by the wireless transmission / reception means via the wireless communication line, on a recording medium; and the child When the external image forming data is received from the external communication line during image formation by the image forming means based on the slave image forming data transmitted from the machine, an image formation data transmission interruption request to the slave unit Image forming control means for performing image formation by the image forming means on the basis of the external image forming data received from the external communication line, and the slave unit transmits the interruption request to the slave unit side wireless transmission / reception means. Wireless communication control means for transmitting to, the slave unit is at least a data input unit for inputting non-voice data, and the master unit In the meantime, in the communication apparatus comprising a slave unit side wireless transmission / reception unit that wirelessly transmits / receives at least non-voice data at a timing synchronized with the parent unit by a frequency hopping method, the image formation control unit includes the external device When image formation based on the external image formation data received from the communication line is completed, an image formation data transmission restart request is output to the slave unit, and the wireless communication control unit After transmitting the request, the base unit side radio transceiver unit and the slave unit side radio transceiver unit stop frequency hopping, and after the restart request is transmitted to the slave unit, the frequency hopping is restarted. , Outputting an image formation restart request based on the slave unit image formation data transmitted from the slave unit to the image formation control means, and the restart request If there is no response from the slave unit, the restart frequency is changed and the restart request is transmitted again.
[0025]
  Claim1According to the communication device described above, the wireless communication control unit causes the base unit side wireless transmission / reception unit to transmit the suspension request to the slave unit, and then the base unit side wireless transmission / reception unit and the slave unit The side wireless transmission / reception means stops frequency hopping. The image formation control unit causes the image formation unit to perform image formation based on the external image formation data received from the external communication line, and when the image formation is completed, An image formation data transmission restart request is output. Next, the wireless communication control unit that has received this output transmits information for resuming the frequency hopping to the slave unit after transmitting the restart request to the slave unit. Thereby, since transmission of the slave unit image formation data is resumed from the slave unit, the wireless communication control unit is based on the slave unit image formation data transmitted from the slave unit to the image formation control unit. A request to resume image formation is output. As a result, image formation based on the slave unit image formation data transmitted from the slave unit is resumed in the master unit. Further, the wireless communication control unit causes the base unit side wireless transmission / reception unit to transmit the restart request to the slave unit, but if there is no response to the restart request from the slave unit, the frequency at the time of restart And restart request is sent again. Therefore, even when communication interruption or the like occurs between the parent device and the child device at the time of the first restart, normal communication is resumed at a different frequency.
[0026]
  Claim2The communication device according to claim 1,1The wireless communication control means includes a finite number of restart frequencies, and the finite number of restart frequencies are sequentially switched and transmitted.
[0027]
  Claim2According to the communication device described in the above, the resumption frequency is changed based on a finite number of resumption frequencies. However, when the disturbance state is released, normal communication is resumed at any frequency. Therefore, the storage area for the restart frequency is small.
[0028]
  Claim3The communication device described in (1) includes: a master unit connected to at least one external communication line; and a slave unit that generates at least one non-voice data connected to the radio communication line by the frequency hopping method with the master unit. The master device includes an external transmission / reception unit that transmits / receives data through the external communication line, a data type determination unit that determines a type of data to be transmitted / received, and data that is determined by the data type determination unit Wirelessly transmits and receives at least non-speech data by frequency hopping between the data conversion means for converting data into a format that can be handled either on the external communication line side or on the device internal side according to the type External image forming data which is image forming data received by the base side wireless transmitting / receiving means and the external line transmitting / receiving means via the external communication line, or Image forming means for visualizing at least one of slave image forming data, which is image forming data transmitted from a slave and received by the wireless transmission / reception means via the wireless communication line, on a recording medium; and the child When the external image forming data is received from the external communication line during image formation by the image forming means based on the slave image forming data transmitted from the machine, an image formation data transmission interruption request to the slave unit Image forming control means for performing image formation by the image forming means on the basis of the external image forming data received from the external communication line, and the slave unit transmits the interruption request to the slave unit side wireless transmission / reception means. Wireless communication control means for transmitting to, the slave unit is at least a data input unit for inputting non-voice data, and the master unit In the meantime, in a communication apparatus comprising a slave unit side wireless transmission / reception means for wirelessly transmitting / receiving at least non-voice data at a timing synchronized with the base unit by frequency hopping method, the voice data connected to the wireless communication line At least one handset that handles voice data and non-voice data via the external communication line as the external line transmission / reception means, and the non-voice data is handled as the master side wireless transmission / reception means. A means for wirelessly transmitting and receiving both the non-voice data and the voice data by a frequency hopping method by a time division process between the slave unit and the slave unit handling the voice data, and in one frame which is one unit of the wireless transmission and reception Is divided into a slot for voice and a slot for non-voice, and the slot is assigned according to the type of the data A base unit side slot allocation control unit is further provided, and at least one of the voice data and the non-voice data is transmitted to the base unit or the other unit as the slave unit side wireless transmission / reception unit. Comprising: a means for performing wireless transmission / reception by a frequency hopping method based on time division processing synchronized with the wireless transmission / reception timing of the slave unit, and further comprising a slave unit side slot allocation control unit for allocating the slot according to the type of the data It is characterized by.
[0029]
  Claim3According to the communication device described in the above, not only non-voice data but also voice data is transmitted / received via the external communication line and the wireless communication line. Audio data is wirelessly transmitted and received by a frequency hopping method by time division processing. One frame, which is a unit for wireless transmission / reception, is divided into a slot for voice and a slot for non-voice, and the master unit side uses slot allocation control means on the master unit side, and the slave unit on the slave unit side. The slot assignment control means assigns slots according to the data type. Therefore, even when both voice data and non-voice data are wirelessly communicated between the master unit and the slave unit, each of the voice data and the non-voice data is transmitted during one communication unit in the spectrum spread digital communication system. Since the occupying ratio is appropriately switched according to the type of data or the wireless communication state, appropriate wireless communication according to the nature of the data is performed. Therefore, even during image formation based on the external image formation data from the external communication line after the interruption request, communication between the parent device and the child device by the audio data or external line communication from the child device is possible.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, embodiments of the invention will be described with reference to the drawings.
[0031]
  (First Embodiment) First, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing a schematic configuration of a parent device and a slave device constituting a communication device according to the first embodiment of the present invention, and FIG. 2 is a block diagram showing a schematic configuration of the entire communication device according to this embodiment.
[0032]
  As shown in FIG. 2, the communication apparatus according to this embodiment includes a master unit 1 wired to a general commercial analog telephone line, and four voice terminals that are wirelessly connected to the master unit 1 by a frequency hopping method. It is comprised from the machine 20A-20D and the four data terminal subunit | mobile_units 40A-40D.
[0033]
  First, the configuration of base unit 1 will be described. The master unit 1 is a multi-function device having a scanner function, a facsimile function, a print function, and a master / slave telephone function. As shown in FIG. 1A, an NCU (Network Control) for controlling an external analog telephone line is used. Unit) 2, voice codecs 3 a, 3 b, 4 as data conversion means for performing digital encoding of voice data, and data conversion means having a facsimile transmission / reception function and a personal computer communication data transmission / reception function An image reading block 7 as a data input means composed of a transmitter / receiver 6 as a master side radio transmitting / receiving means for performing a frequency hopping wireless communication described later between the modem 5 and the slave unit. An image output block 8 as an image forming means for forming an image on a recording material, a handset 9 for making an external line call or an internal line call from the master unit 1, and for controlling each of these means or devices. Unit, parent side wired transmission / reception unit, data type discrimination unit, image formation control unit, wireless communication control unit, and parent unit side switching control unit A CPU 10 as a stage, a ROM 11 storing a program or data for operating the CPU 10, and a RAM 12 for temporarily storing arithmetic processing data during operation of the CPU 10 are provided.
[0034]
  Note that an operation unit including a switch for operating the parent device 1 is not shown. In FIG. 1A, a solid line connecting each means and device represents a control line, and a dotted line represents a data line.
[0035]
  Next, the configuration of each means and apparatus that constitutes the above master unit 1 will be described in detail.
[0036]
  As shown in FIG. 1A, the NCU 2 for performing the outside line control is connected to four analog telephone lines of the outside line (1), the outside line (2), the outside line (3), and the outside line (4). The voice codec 3a, 3b or the modem 5 is connected under the control of the CPU 10.
[0037]
  The audio codecs 3a and 3b are means for analog-to-digital conversion of audio data under the control of the CPU 10, and convert audio data digitally encoded from the slave units 20A to 20D to analog data, or the CPU 10 In order to transmit the analog voice data received from the handset 9 via the NCU 2 from the external line to the slave units 20A to 20D, digital coding is performed.
[0038]
  The modem 5 realizes terminal characteristics and transmission procedures that adopt class 2 (EIA-592), which is currently established as a FAX modem, and performs data compression encoding by the MH (Modified Huffman) method and the like. Data transmission / reception with the telephone line network is performed at the transmission speed. It also has a block that converts or reversely converts it into a data format suitable for wireless transmission / reception.
[0039]
  A detailed configuration of the transmitter / receiver 6 is shown in FIG. As shown in FIG. 3, the transmission / reception device 6 includes a hop frequency data generation unit 31 that generates hop frequency data used for switching frequencies in a predetermined hopping pattern, and hop frequency data provided from the hop frequency data generation unit 31. And a communication unit 32 that spreads an input signal into a transmission signal and despreads a reception signal into an output signal.
[0040]
  The hop frequency data generation unit 31 includes a frame counter 34 that is incremented every time an output signal from the clock 33 is input, a hopping counter 35 that is incremented every time a hopping start signal is input from the frame counter 34, The hop frequency data is read out from the hopping table 36 in accordance with the input value from the hopping counter 35 that sequentially changes, and the hop frequency data is generated as an output signal. . Note that the frame counter 34, the hopping counter 35, and the hopping table 36 may be configured separately as described above, but can be replaced with calculations performed by the CPU 10.
  Further, when the hop frequency data is given from the hop frequency data generating unit 31, the communication unit 32 receives the oscillation frequency f corresponding to the hop frequency data._NFrequency synthesizer 37 that oscillates at ′, and the oscillation frequency f from the frequency synthesizer 37_N'And the data from the voice codec 3a, 3b or the modem 5 are modulated by the modulator 54, and the frequency f_1FAre transmitted by the up converter 38 and the frequency f output from the up converter 38 is mixed._NThe transmission signal is amplified by an amplifier 39, and the signal is transmitted from the antenna 6a via the duplexer 50. On the other hand, the frequency f received by the antenna 6a._NIs input to the amplifier 51 via the duplexer 50 and amplified, and the frequency f_NAnd the oscillation frequency f from the frequency synthesizer 37_N'Is mixed by the down converter 52, and the frequency f_1FThe received output signal is generated.
[0041]
  The frequency f_1FAfter being demodulated by the demodulator 55, the received output signal is output to the audio codecs 3a, 3b, 3c or the modem 5 shown in FIG. The synchronization circuit 53 detects the phase of the hopping frequency from the received output signal, and the synchronization circuit 53 outputs the synchronization signal to the hopping counter 35. The hopping counter 35 performs output to the hopping table 36 according to the input synchronization signal, hop frequency data is read from the hopping table 36, and the hop frequency data is generated as an output signal.
[0042]
  FIG. 4 shows an example of hop frequency switching by the transmission / reception apparatus 6 as described above. In the example shown in FIG. 4, the hop frequency is switched every period T.
[0043]
  In the present embodiment, a hopping frequency data string as shown in FIG. In this embodiment, as shown in FIG. 5, three different hopping frequency data sequences of channels 1, 2, and 3 are used, and the contents of frequency data constituting each frequency data sequence are different from each other. Therefore, for example, even if channel 1 is used for communication between the parent device and the child device, channel 2 can be used for communication between the child devices, and channel 3 can be used for communication between other child devices. Simultaneous communication between multiple devices is possible by channelization.
[0044]
  Next, the image reading block 7 is provided with image reading means such as a scanner. Image data read by the image reading means is temporarily stored in the buffer 7a, and the image output block 8 described below is controlled by the CPU 10. The image is output or transmitted to the outside line or the handset side via the modem 5.
[0045]
  The image output block 8 is means for outputting an image of data stored in the buffer 8a. The image output block 8 includes, for example, a means using a photosensitive drum using an electrophotographic method, a thermal transfer means using a thermal head, or an inkjet head. It is comprised by the means etc. The data stored in the buffer 8a includes facsimile data received via an external line, image data transmitted from the slave units 40A to 40D, and image data read by the image reading block 7.
[0046]
  The handset 9 includes a microphone, a speaker, and the like (not shown), and enables an external call from the parent device 1 itself or an extension call to the child devices 20A to 20D.
[0047]
  The CPU 10 performs internal / external line communication control in response to a communication request from an external line or a slave unit, slot allocation control within one frame, which is a unit of communication, management of a communication control table, type determination of transmitted / received data, etc. However, details will be described later.
[0048]
  In addition to the program for operating the CPU 10, the ROM 11 stores a hardware allocation table and the like as a basis for creating a communication control table. The table will be described later.
[0049]
  The RAM 12 temporarily stores data used for arithmetic processing during the operation of the CPU 10 and stores a communication control table. The table will be described later.
[0050]
  The above is the configuration of each means and device of the base unit 1. Next, the structure of subunit | mobile_unit 20A-20D is demonstrated.
[0051]
  Slave units 20A to 20D are cordless telephones, and as shown in FIG. 1B, microphone 21A for inputting voice, speaker 22A for outputting voice, and analog input from microphone 21A An audio codec 24A as data generating means for converting audio data into digital audio data, converting the digital audio data into analog audio data and outputting the analog audio data to the speaker 22A, and a slave unit for transmitting and receiving data via the antenna 26A A transmission / reception device 25A as a side wireless transmission / reception means and a CPU 27A as a selection control means for controlling them are provided.
[0052]
  The microphone 21A and the speaker 22A are accommodated in the case of the cordless telephone so as to function as a transmitter and a receiver. The audio input from the microphone 21A is converted into an audio data signal by the audio codec 24A having the same configuration as that of the audio codec 3a, 3b, 3c of the base unit 1, and the frequency having the same configuration as that of the transmission / reception device 6 of the base unit 1 The signal is converted into a predetermined signal by the transmission / reception device 25A that performs hopping transmission / reception and transmitted from the antenna 26A. On the other hand, a predetermined signal received by the antenna 26A is extracted only by the transmitting / receiving device 25A, converted into an analog audio signal by the audio codec 24A, and output to the speaker 22A. The CPU 27A, like the CPU 10 of the parent device 1, performs slot allocation control, table management of the child devices, etc., which will be described in detail later. In addition, this structure is the same also about the subunit | mobile_unit 20B-20D.
[0053]
  Next, the configuration of the slave unit 40A will be described. The handset 40A is a data terminal that handles non-voice data such as a personal computer or PDA (Personal Digital Assistants). As shown in FIG. 1C, the display device 41A using a liquid crystal or the like, various calculations or CPU 42A as slave unit side switching control means for performing data processing and further data transmission / reception processing, ROM 43A storing a program or data for operating CPU 42A, arithmetic processing data during operation of CPU 42A, etc. For transmitting and receiving data by a frequency hopping method as will be described later between the RAM 44A for temporarily storing the data, the modem 45A having a data transmission / reception function, and the main unit 1 via the antenna 47A. A transmission / reception device 46A serving as a machine-side wireless transmission / reception means. Note that an illustration of an operation unit including a switch or the like for operating the slave unit 40A is omitted. Moreover, it becomes the structure similar to the subunit | mobile_unit 40B-40D.
[0054]
  The transmission / reception device 46A of the child device 40A has the same configuration as the transmission / reception device 6 of the parent device 1, and transmits and receives data by the frequency hopping method. Unlike the modem 5 of the master unit 1, the modem 45A is a block that converts a digital signal into a data format suitable for wireless transmission and reception, and a block that performs the inverse conversion. The facsimile data and image data transmitted from the outside line via the master unit 1 can be read, or the facsimile data and image data created on the slave unit 40A can be transmitted via the master unit 1.
[0055]
  As shown in FIG. 2, the communication apparatus according to the present embodiment includes one master unit 1 as described above, four slave units 20A to 20D as voice data terminals, and four units as non-voice data terminals. The slave units 40A to 40D are provided and have the following functions.
[0056]
  a. External phone call using the handset 9 alone
  b. FAX transmission / reception by the master unit 1 using the image reading block 7 and the image output block 8
  c. An extension call between the main unit 1 and any one of the sub units 20A to 20D
  d. External phone calls via the master unit 1 by the slave units 20A to 20D
  e. Image output by the master unit 1 using the image output block 8 of the output data from the slave units 40A to 40D, or FAX transmission of the data via the master unit 1
  f. Data read by the slave unit 40A to 40D by the master unit 1 by the image reading block 7 or by FAX reception
  g. External communication via the master unit 1 by the slave units 40 </ b> A to 40 </ b> D, that is, the master unit 1 responds to a communication request from each slave unit or an instruction input from the operation unit of the master unit 1. Are determined, and a means, device, or line in the base unit 1 to be used is selected according to the data, and appropriate communication processing is performed.
[0057]
  The types of data handled include voice data, FAX data, and personal computer communication data received via an external analog telephone line, and all these data are transmitted between the master unit 1 and each slave unit. Wireless transmission / reception will occur.
[0058]
  And in the communication apparatus of this embodiment, when performing frequency hopping bidirectional communication using TDD (Time Division Duplex) as described later, the audio data and non-audio data are mixed. In order to enable communication between the master unit and the slave unit, the type of data to be transmitted / received by dividing one frame, which is a unit of transmission / reception, into a slot for voice data and a slot for non-voice data Depending on the situation, the slot allocation process is performed.
[0059]
  FIG. 6 shows a frame configuration used in the present embodiment. The frame 70 used in the master unit 1 includes an occupied time slot 71, a voice terminal data reception slot 72 such as the slave units 20A to 20D, and a data terminal data transmission / reception slot 73 such as the slave units 40A to 40D. A voice terminal data transmission slot 74 is provided. On the other hand, the frame 80 used in the slave units 20A to 20D and 40A to 40D has substantially the same configuration as the frame 70, and includes an occupied time slot 81, a voice terminal data transmission slot 82, and data terminal data. A transmission / reception slot 83 and a voice terminal data reception slot 84 are provided.
[0060]
  These slots are managed based on the elapsed time when the transmission / reception start time is set to 0, and transmission / reception of audio data and non-audio data is performed by transmitting / receiving frames in units of such slots. Will be performed in a time-sharing manner. Since synchronization is established between the master unit and the slave unit so that the transmission / reception start timings of these frames coincide with each other, data can be transmitted / received between the master unit and the slave unit. ing.
[0061]
  Next, a specific example of transmission / reception processing when a frame having such a structure is used will be described.
[0062]
  First, when transmission / reception is started, since the occupied time slots 71 and 81 are in the period from 0 to t1, no data is transmitted / received between the parent device and the child device. The occupation time is a time for stabilization at the frequency after the hop in the frequency hopping method shown as the period t in FIG. 4, and in order to perform accurate data transmission / reception, any data transmission / reception until the occupation time ends. Is not done.
[0063]
  Next, the period from t1 to t2 is the voice data reception slot 72 for the voice terminal on the base unit side and the voice data transmission slot 82 for the voice terminal on the handset side. Any one of ˜20D transmits audio data during this period, and base unit 1 receives the audio data.
[0064]
  Next, since the period from t2 to t3 is the non-voice data transmission / reception slots 73 and 83 for the data terminal, for example, when there is transmission data from any of the slave terminals 40A to 40D for the data terminal, The transmission data is transmitted to the parent device 1 during this period, and the parent device 1 receives the data during this period. Similarly, when there is communication data from the outside through an external line, the base unit 1 transmits data to any of the handset units 40A to 40D during the non-voice data transmission / reception slot 73 for the data terminal. Any of the slave units 40A to 40D receives the data during this period.
[0065]
  Next, during the period from t3 to t4, the voice data transmission slot 74 for voice terminals is used on the parent device side, and the voice data reception slot 84 for voice terminals is used on the slave device side. When there is voice data transmitted from the slave unit in the slot 82 and responding to the voice data received by the master unit in the voice terminal voice data reception slot 72, the voice terminal voice data transmission slot At 74, the audio data is transmitted from the parent device 1, and the data is received by the child devices 20A to 20D during this period.
[0066]
  In this embodiment, since communication is performed using a frame constituted by a slot for voice data and a slot for non-voice data in this way, communication between one voice terminal slave unit and the master unit, and 1 Communication between the slave terminal for the data terminal and the master unit can be performed simultaneously.
[0067]
  In addition, since the frame counter 34 is incremented for each frame and the frequency is sequentially hopped, the frequency can be effectively used and the secrecy can be improved.
[0068]
  Furthermore, although the length of one frame shown in the period of 0 to t4 in FIG. 6 is fixed in this embodiment, the length of each slot is variable depending on the size of audio data or non-audio data, and efficient communication is possible. Is possible. For audio data, a transmission slot and a reception slot are always provided in one frame, so simultaneous bidirectional communication is possible. On the other hand, for non-voice data, it is considered that there is little need for simultaneous bi-directional communication, so either transmission or reception is performed within one slot. For this reason, the transmission / reception switching may be performed only at one of t2 and t3, and the control becomes simple.
[0069]
  Next, the data structure of the slot as described above will be described in detail with reference to FIG. First, the voice terminal transmission / reception slot 90 includes a preamble 91, control data 92, a transmission-side terminal identification ID 93, a reception-side terminal identification ID 94, and audio data 95 including a correction code. In the present embodiment, audio data is transmitted and received without being compressed, but may be compressed by an audio codec in relation to the communication speed. Further, the correction code is not an essential component for the present invention.
[0070]
  The preamble 91 ensures that all components of the communication line are adjusted to an appropriate state so that subsequent data is transmitted without loss.
[0071]
  The control data 92 includes an in-slot data length and data identification information.
[0072]
  The in-slot data length is information for notifying the separation or interval of each slot, for example, the values at times t2, t3, and t4 shown in FIG. As described above, since the slot length is variable according to the data length, the receiving side refers to the data length in the slot included in the control data, so that the data can be received correctly without causing a synchronization shift. It can be carried out. Note that a time margin is taken into account between each slot in consideration of propagation delay.
[0073]
  The data identification information is information for identifying whether the data transmitted in this slot is the voice data or the non-voice data, the data for synchronization, or the control data. The data for synchronization is data transmitted at the time of acquisition of synchronization, which will be described later, and will be described in detail when explaining the acquisition of synchronization. The control data is data that informs a communication request or information such as permission or rejection for the request.
[0074]
  The transmission-side terminal identification ID 93 is an ID number added to each device on the transmission side. With this information, the receiving side can identify the transmitting side and the type of data to be transmitted.
[0075]
  The receiving side terminal identification ID 94 is an ID number added to each receiving side device. With this information, the receiving side can correctly select only the data transmitted to itself, and proper communication can be performed. Will be done.
[0076]
  The audio data 95 is data after being encoded by the audio codec as described above, and an error correction code is added thereto. This correction code is obtained by adding predetermined redundant bits to audio data to be transmitted by a predetermined error encoding method. For example, a BCH (Bose-Chaudhuri-Hocquenghem) code or an RS (Read-Solomon) code is used. The error correction coding used can be mentioned.
[0077]
  Next, the configuration of the transmission / reception slot 100 for data terminals is substantially the same as the configuration of the voice data transmission / reception slot for voice terminals, and includes a preamble 101, control data 102, transmission-side terminal identification ID 103, reception-side terminal identification ID 104, and It consists of data 105 to which an error correction code is added.
[0078]
  Among these, the control data 102 includes next transmission terminal information, unlike the control data 92 of the voice terminal voice data transmission / reception slot 90. This next transmission terminal information is information indicating which terminal will transmit data in the next frame. That is, as described above, since the slot for the data terminal is used only for transmission or reception for one frame, the transmission direction between communication devices is determined by the next terminal information. . Since data with a large amount of information, such as image information, is often transmitted unilaterally, for example, when transmitting image information from a slave unit to a master unit, the next transmission information is set in the slave unit while the slave unit is set. Keep sending from the machine.
[0079]
  Further, the communication between the parent device and the child device and the communication between the child device and the child device as described above must be synchronized with each device. Therefore, in the communication apparatus of this embodiment, the following synchronization acquisition process is performed. In this synchronous acquisition process, the master unit and the slave unit exchange transmission and reception at a control frequency that exists for a certain period of time, and the master unit sends the master unit to the slave unit registered in the master unit. Send data to check if it can be synchronized with.
[0080]
  FIG. 8 is a timing chart for explaining the synchronization acquisition process. The master unit 1 transmits synchronization acquisition data to each slave unit by using the synchronization acquisition transmission frames 106 and 107. Each slave unit is a master unit. The response data is transmitted to the base unit 1 by the response frames 108a to 108h at the timing designated from 1.
[0081]
  In the synchronization acquisition transmission frame, a synchronization acquisition slot as shown in FIG. 9 is used. As shown in FIG. 9, the synchronization acquisition slot 110 transmitted from the parent device to the child device includes a preamble 111, control data 112, transmission-side terminal identification ID 113, reception-side terminal identification ID 114, and synchronization acquisition data 115. It consists of each data. The preamble 111, the control data 112, the transmission side terminal identification ID 113, and the reception side terminal identification ID 114 have the same configuration as that in the normal data transmission / reception slot shown in FIG.
[0082]
  However, in the synchronization acquisition data 115, the time for synchronization and information on the next channel and slot are transmitted. The time for synchronization is the transmission start time based on the transmission frame for acquisition of synchronization, and in FIG. 8, the times are t10, t20, t30, t40, t50, t60, t70, and t80.
[0083]
  The next channel refers to any of the channels shown in FIG. 5, and the next slot refers to the transmission timing within one frame. For example, in the example of FIG. 8, in the frame 108 where transmission starts from time t10, response data from the slave unit is transmitted at time t11. This time t11 corresponds to the “next slot”.
[0084]
  As described above, the response from each slave unit is performed by the response frames 108a to 108h as shown in FIG. 8, and the response slot 120 as shown in FIG. 9 is used in the response frame. As shown in FIG. 9, the response slot 120 transmitted from the slave unit to the master unit includes the preamble 121, the control data 122, the transmission side terminal identification ID 123, the reception side terminal identification ID 124, and the response data 125. It is composed of The preamble 121, the control data 122, the transmission side terminal identification ID 123, and the reception side terminal identification ID 124 have the same configuration as that in the normal data transmission / reception slot shown in FIG.
[0085]
  However, in the response data 125, information on the reception level, the communication partner terminal, the request channel, the request slot, and the current state is transmitted.
[0086]
  The reception level is information indicating whether or not the synchronization acquisition data from the base unit 1 has been normally received. The base unit 1 is information indicating that the reception level from the slave unit is good at the designated channel and timing. When it is received, it is determined that the slave unit has been synchronized.
[0087]
  The communication partner terminal is used when making a communication request to the outside in addition to the reception level information from the slave unit, and is not always transmitted. For example, it is information indicating an outside line, a parent device, another child device, and the like.
[0088]
  The request channel and slot are also used only when there is a communication request from the slave unit. Usually, the master unit 1 performs channel and slot assignment for the communication request from the slave unit, as will be described later. Therefore, it is not used in this embodiment.
[0089]
  The current status indicates what communication status the slave unit is currently in. “Waiting”, “During communication between slave unit and slave unit”, and “During communication between master unit and slave unit” There are various states.
[0090]
  Next, a specific example of the synchronization acquisition process using the frames and slots as described above will be described.
[0091]
  First, in the synchronization acquisition frame 106, the master unit 1 transmits synchronization acquisition data to all of the slave units 20A to 20D and the slave units 40A to 40D. In this transmission, the receiving side ID 114 in the synchronization acquisition slot 110 shown in FIG. 9 is further divided into a plurality of IDs for each slave unit, and the synchronization acquisition data 115 is also divided into a plurality. The acquisition data for each slave unit may be continuously transmitted. Alternatively, the receiving side ID 114 and the synchronization acquisition data 115 may be paired and the pair may be repeatedly transmitted for each slave unit. Alternatively, the synchronization common ID and common data may be transmitted instead of the individual ID of each slave unit.
[0092]
  The slave side that has received the transmission data from the base unit 1 side by the above method transmits information on whether or not the reception level is good by the response slot 120 at the time designated by the base unit 1. When there is a communication request from the child device side to the parent device side, the communication request is made at the time of this response. When there is no communication request, only the current state is transmitted.
[0093]
  Then, the master unit that has received the data in the slot 120 as described above from the slave unit determines that the synchronization is established if the reception level is good, and determines that the synchronization is not established if the reception level is negative. The communication control table to be described later is rewritten.
[0094]
  Further, when there is a communication request from the slave unit to the synchronized slave unit, a response to the slave unit is sent from the communication processing slot 130 shown in FIG. Do. The communication processing slot 130 includes a preamble 131, control data 132, a transmission side terminal identification ID 133, a reception side terminal identification ID 134, and communication processing data 135. The control data 132, the transmission side terminal identification ID 133, and the reception side terminal identification ID 134 are the same as those described above.
[0095]
  However, the communication processing data 135 includes permission / rejection information for the communication request from the slave unit and information on the next channel and slot.
[0096]
  The communication processing slot 130 transmits communication processing data to each slave unit in the transmission frame 107 shown in FIG. 8, thereby controlling communication between the slave unit and other devices. .
[0097]
  However, when the transmission data of the master unit 1 is disturbed as in the case of the slave unit 40D shown in FIG. 8, or the transmission data from the slave unit is disturbed as in the slave unit 20D, 2 In the transmission frame 107 for the second time, the base unit 1 repeats transmission by the synchronization acquisition slot 110 shown in FIG. 9 to the handset 20D and handset 40D.
[0098]
  On the other hand, the slave units 20D and 40D that do not receive the transmission signal from the master unit 1 monitor the control signal output by the master unit 1 without sending any transmission signal to the master unit 1. Therefore, when the disturbing state is resolved, the slave units 20D and 40D can communicate with each other.
[0099]
  Next, when there is a communication request from each slave unit, a communication request from an external line, or a call request by the handset of the master unit itself at the time of synchronization acquisition as described above, the voice codec 3a, 3b or modem The process of assigning each line to 5 or the process of assigning the voice data or non-voice data to each slot of the communication frame will be described.
[0100]
  In the present embodiment, the voice codecs 3a and 3b and the modem 5 cannot be connected to two lines at the same time, and the communication frame is assigned to only one device in each of the voice data slot and the data slot. Therefore, various allocation processes as described above are performed in accordance with the current communication status and the type of data to be transmitted / received.
[0101]
  Specifically, the CPU 10 of the base unit 1 manages the communication status, the connection status of each hardware, and the slot assignment in a table formed on the RAM 12 as shown in FIG.
[0102]
  The RAM 12 has a table area in addition to a FAX data storage area, a data storage area, and an audio memory storage area, and the table is stored in this table area.
[0103]
  FIG. 10A is an external line management table showing an external line connection state, and is divided into an area 140 indicating the type of external line and an area 141 indicating the connection state of the external line. External line (1), external line (2), external line (3), and external line (4) are assigned to area 140 indicating the type of external line, and each external line is connected to area 141 indicating the connection state with the external line. The state is stored. Therefore, it is possible to grasp which hardware is connected to each external line by referring to the external line management table. In the state shown in FIG. 10A, the outside line (1) is in IDLE, that is, in a standby state and is not used. The external line (2) is connected to the voice codec 3a, the external line (3) is connected to the modem 5, and the external line (4) is in IDLE, that is, in a standby state.
[0104]
  Next, FIG. 10B is a hardware management table showing what kind of data input / output terminals each hardware is connected to in the master unit, and an area 142 indicating the type of hardware and the control in the master unit. It is divided into a region 143 indicating the state. An audio codec 3a, an audio codec 3b, and a modem 5 are assigned to the area 142 indicating the type of hardware. Further, an area 143 indicating the control state in the master unit stores how each hardware is controlled. Therefore, by referring to the hardware management table, it is possible to grasp what data input terminal each hardware is connected to. In the state shown in FIG. 10B, the voice codec 3a is connected to the slave unit 20A, the voice codec 3b is in IDLE, that is, in a standby state, and the modem 5 is connected to the image output block 8 and the slave unit 40A. I understand that.
[0105]
  Accordingly, by referring to the external line management table and the hardware management table as described above, the handset 20A is in an external line call with the external line (2) via the voice codec 3a, and is received from the external line (3). It can be seen that the data is output to the image output block 8 in the master unit via the modem 5 and transmitted to the slave unit 40A.
[0106]
  Next, FIG. 10C is a communication control table for managing the communication status, slot allocation, used channel, and synchronization acquisition status of the master unit and the slave unit. The table includes an area 144 indicating a master unit and a slave unit, an area 145 indicating a communication partner terminal, an area 146 indicating an allocation status of a slot, an area 147 indicating a used frequency channel, and information on synchronization acquisition. And a region 148 indicating.
[0107]
  The base unit 1, the slave unit 20A to the slave unit 20D, and the slave unit 40A to the slave unit 40D are allocated to the area 144 indicating the master unit and the slave unit, and the area 145 indicating the communication partner terminal and the slot allocation status The area 146 indicating the frequency of use, the area 147 indicating the frequency channel used, and the area 148 indicating the information about the synchronization acquisition are divided to correspond to the area 144 indicating the master unit and the slave unit, respectively.
[0108]
  In the area 145 indicating the communication partner terminal, IDLE information indicating a state in which communication is not performed is stored in addition to the parent device 1, the child devices 20A to 20D, and the child devices 40A to 40D. In the case of an outside line call, information to that effect is also added. These pieces of information are rewritten based on the transmission-side ID data or the reception-side ID data in the above-described audio data or non-audio data slot. In the state shown in FIG. 10C, it can be seen that the master unit 1 is communicating with the slave unit 20A for the external line call of the slave unit 20A and is performing extension communication with the slave unit 40C. Further, regarding the slave unit 20A, the master unit 1, the slave unit 20B communicate with the slave unit 20C, and the slave unit 20C communicates with the slave unit 20B, and the slave unit 20D is in a communication standby state with IDLE. . Furthermore, the slave unit 40A communicates with the slave unit 40B, the slave unit 40B communicates with the slave unit 40A, the slave unit 40C communicates with the master unit 1, and the slave unit 40D is in a standby state. Recognize.
[0109]
  In the area 146 indicating the slot allocation status, information indicating that the slot is a voice slot, a data slot, or a single slot is stored, and the communication between devices that can be specified by the areas 145 and 146 is determined. It shows what is done with different slots. When there is a communication request from an external line, these pieces of information are determined based on the type of call signal at that time, and when there is a communication request from the slave unit, the information is determined based on the type of the slave unit. Further, when there is a communication request from the parent device, it is determined whether the handset 9 is used or a FAX transmission / reception button (not shown) is used. Details will be described later. By referring to the contents of this area 146, the empty state of the slot can be known. In the example of FIG. 10C, the voice slot is allocated for communication between the slave unit 20A and the master unit 1 for an external call by the slave unit 20A, and the data slot is used for communication by the slave unit 40C. Therefore, it can be seen that the communication is assigned for communication between the slave device 40C and the master device 1. In addition, a single slot different from the communication slot between the master unit and the slave unit is assigned to the communication between the slave units by the slave unit 20B and the slave unit 20C. It can be seen that another single slot is assigned to the communication between the slave units.
[0110]
  An area 147 indicating the used frequency channel indicates which channel is allocated for communication between the devices. These pieces of information are determined and stored at the time of slot assignment processing described later. By referring to the contents of this area 147, the free state of the channel can be known. In the example of FIG. 10C, channel 1 is assigned to the communication between the parent device 1 and the child device 20A for the external call of the child device 20A, and channel 1 is also used for the extension communication between the child device 40C and the parent device 1. It can be seen that is assigned. The reason why communication is possible on the same channel is that the types of slots assigned to the slave unit 20A and the slave unit 40C are different. Further, channel 2 is assigned to the extension call between the slave unit 20B and the slave unit 20C, and channel 3 is assigned to the extension communication between the slave unit 40A and the slave unit 40B.
[0111]
  In the area 148 indicating information on synchronization acquisition, information indicating “good” is received when good reception level data can be received at a predetermined timing during the above-mentioned synchronization acquisition, and “x” is stored when reception is not possible. Is done. By referring to the contents of this area 148, it can be determined whether or not a communication permission signal can be transmitted to the child device that has issued the communication request.
[0112]
  By referring to the communication control table as described above, it is possible to grasp what kind of counterpart the master unit 1 and each slave unit are currently communicating with, and what kind of slot and channel. Thus, it is possible to accurately determine the slot and channel allocation for the device that requested the communication.
[0113]
  Hereinafter, communication processing including slot and channel allocation processing in the present embodiment will be described with reference to the flowcharts of FIGS.
[0114]
  First, when there is no communication request from the slave unit (step S1; NO), there is no communication request from the handset of the master unit (step S3; NO), and there is no communication request from the outside line (step S5; NO), the process proceeds to the communication end monitoring process (step S6). This communication end monitoring process is shown in FIG. 14, and if communication is not currently being performed and the operation of the master unit alone is not being performed (step S60; NO to step S61; NO), this will be described later. It is determined whether or not it is the FAX interrupt mode to be performed (step S304). In this case, since it is not the FAX interrupt mode (step S304; NO), the communication process is resumed (step S62), as shown in FIG. Next, the communication request presence / absence determination processing from each device is performed (steps S1 to S3 to S5), and the apparatus enters a standby state.
[0115]
  Here, a case where there is a communication request from an outside line (step S1; NO to step S3; NO to step S5; YES) will be described. In this case, the CPU 10 determines whether or not communication between the parent device 1 and the data terminal child device is in progress based on the communication control table for a FAX interrupt process to be described later (step S300). Then (step S300; NO), in order to determine whether the data transmitted from the outside line is non-voice data such as FAX data or voice data, the outside line and the voice codec 3a or 3b or the modem 5 are connected. Then, the transmission data is captured.
[0116]
  Therefore, it is determined by the hardware management table whether or not both of the audio codecs 3a and 3b are in use (step S8). If all the audio codecs are in use (step S8; YES), the same applies to the following. Whether the modem 5 is in use is determined using the hardware management table (step S9). As a result, when the modem 5 is also in use (step S9; YES), since transmission data cannot be captured, a signal rejecting the communication request is transmitted to the outside line as shown in FIG. S130), the process proceeds to a communication end monitoring process (step S131).
[0117]
  However, if any of the voice codecs is usable (step S8; NO), the usable voice codec is connected to the outside line (step S16), and the contents of the outside line management table are rewritten (step S17). That is, information corresponding to the usable voice codec is stored in an area corresponding to an external line for which a communication request has been made in the area 141 of the external line management table. Then, the transmission data is fetched into the CPU 10 via the usable voice codec, the data is analyzed, and it is determined whether or not this data can be recognized as voice data (step S18). As a result, when it can be recognized as voice data (step S18; YES), the routine proceeds to voice data call processing (step S21). This calling process for voice data is shown in FIG. 12, and will be described later in detail.
[0118]
  On the other hand, if it cannot be recognized as voice data (step S18; NO), the voice codec connected to the outside line is released (step S19), and the area of the outside line management table rewritten earlier is rewritten to IDLE. However, since the transmission data is not voice data but may be FAX data or other communication data, it is next determined whether or not the modem 5 is in use (step S9). As described above, the determination process also proceeds when all the audio codecs are in use (step S8; YES). If the modem 5 can be used (step S9; NO), the modem 5 is connected to the outside line to establish a protocol (step S10), and the contents of the outside line management table are the same as in the case of the voice codec. Is rewritten (step S11). Next, the data taken in via the modem 5 is analyzed to determine whether or not it can be recognized as FAX data or other communication data (step S12). When the data cannot be recognized (step S12; NO) ), Release the modem 5 (step S13), rewrite the contents of the previously rewritten external line management table to IDLE (step S14), and send a request rejection signal for the external line as shown in FIG. 17 (step S130). The process proceeds to the communication end monitoring process (step S131).
[0119]
  However, if it can be recognized that the data is FAX data or other communication data (step S12; YES), the process proceeds to a non-voice data calling process (step S15). This non-voice data calling process is shown in FIG. 15, and will be described in detail later.
[0120]
  Next, the calling process for voice data (step S18; YES to step S21) when it is determined as voice data as a result of the analysis of the transmission data as described above will be described with reference to FIG.
[0121]
  First, in the case of audio data, it is determined based on the communication control table whether all the slave units are in use to call the slave unit (step S30). If all the slave units are in use, (Step S30; YES), whether or not the handset 9 of the parent device 1 is also being used is determined by a hook signal or the like in the parent device 1 (Step S42). If the handset 9 is also in use (step S42; YES), a signal for rejecting the communication request is transmitted to the outside line (step S43), and the voice codec previously connected to the outside line is released (step S43). In step S39), the corresponding part of the outside line management table is rewritten to IDLE (step S40), and the process proceeds to the communication end monitoring process (step S41).
[0122]
  On the other hand, if any of the slave units can be used (step S30; NO), it is determined whether or not the voice slot is usable (step S31). This is because the voice data received from the outside line is wirelessly transmitted to the slave unit through the voice slot to check whether or not the slave unit can make an external line call. Therefore, it is determined whether or not the voice slot is used based on the communication control table area 146. If the voice slot is used (step S31; YES), whether or not the handset 9 is in use as described above. Is determined (step S42), and the same processing as described above is performed.
[0123]
  However, if the voice slot is usable (step S31; NO), a call signal for the child device is created (step S32), and it is further determined whether or not the handset 9 is in use (step S33). This is because if the handset 9 can be used, the handset 9 is also called at the same time as the slave unit. Therefore, if the handset 9 is usable as a result of the determination (step S33; NO), a master call signal is created (step S34). The processing for creating the parent device call signal is also performed when it is determined that the handset 9 can be used when all the child devices cannot be used or the voice slot is in use (step S42; NO).
[0124]
  Then, the calling signal created as described above is transmitted to the child device and / or the parent device (step S35), and a response from each device is waited (step S36). If there is no response from any device (step S36; NO), it waits while determining whether or not to cancel the communication request from the outside line side (step S38). As a result, when the communication request is canceled from the outside line side (step S38; YES), the voice codec previously connected to the outside line is released (step S39), and the corresponding part of the outside line management table is rewritten to IDLE. (Step S40), the process proceeds to a communication end monitoring process (Step S41).
[0125]
  However, if there is a response from any of the devices (step S36; YES), the process proceeds to slot allocation for audio data (step S37). This process is shown in FIG. 13. First, it is determined whether or not the device that has responded is the handset 9 (step S50). If there is a response from the handset 9 (step S50; YES), Connection between the slave unit and the external line is not performed, and an external line call using the handset 9 is started (step S55). On the other hand, if it is not a response by the handset 9 but any one of the slave units (step S50; NO), a voice slot is assigned for wireless communication between the slave unit and the master unit (step S51). In other words, after selecting one of the available channels and determining the transmission ID and reception ID in the voice slot, the channel and slot information determined at the time of synchronization acquisition described above are transmitted to the communication partner's slave unit. To send. Then, after performing such slot allocation processing, communication between the parent device and the child device is started (step S52).
[0126]
  Next, the hardware management table and the communication control table are rewritten (step S53). For example, in the case of an outside line call using the handset 9, information indicating that the connected device is the handset 9 is stored in the area 141 for the outside lines (1) to (4). However, in this case, since the voice slot is not used, the content of the communication control table is not rewritten.
[0127]
  On the other hand, in the case of an external call by any of the slave units, information indicating that the connected device is any of the slave units is stored in the area 143 for the voice codec 3a or 3b. In the communication control table, information indicating that “slave unit 20A (external line)” is stored in the area 145 indicating the communication partner terminal of the base unit 1, and the slot 146 indicates a voice slot. Enables information indicating In the area 147 indicating the channel, “1”, which is a channel that was free at that time, is stored. In this way, communication is performed between the outside line and the handset 9 or the slave unit.
[0128]
  Data transmission / reception processing during communication as described above is executed in parallel by an interrupt routine or the like separately from communication processing such as slot allocation processing described in this embodiment, and table management is performed as described above. When the process ends, the process proceeds to a communication end request monitoring process shown in FIG. 14 (step S54).
[0129]
  As shown in FIG. 14, for example, when there is a call termination request from the slave unit when the slave unit is in an external line communication state (step S60; YES to step S63; YES), the master unit A communication end permission signal is transmitted to the slave unit (step S64), the voice codec or voice slot used for communication with the slave unit is released (step S65), and processing such as clearing of each table is performed. (Step S66), the process returns to the standby state again (step S304; NO to step S62). Also, when there is a communication end request from the handset 9 by an on-hook signal or the like, the same table management processing is performed except for transmission of the communication end permission signal to the slave unit, and the standby state is returned again. The same applies when a communication end request is received from the outside line. The above is the outline of the external line call processing by the handset 9 or the voice terminal slave when there is a communication request from the external line.
[0130]
  Next, a case where there is a communication request from an outside line in FIG. 11 and the transmitted data is non-voice data will be described. In this case, the process proceeds to a non-voice data calling process (step S15).
This process is shown in FIG. 15. First, in order to make a call to the data terminal slave units 40A to 40D, it is determined with reference to the communication control table whether or not these slave units can be used. (Step S70). As a result, when any of the slave units can be used (step S70; NO), by referring to the communication control table whether or not the data slot is being used for wireless communication between the master unit and the slave unit. Determination is made (step S71). As a result, when the data slot is usable (step S71; NO), a calling signal for the slave unit is created (step S72), and a protocol is established (step S73). Specifically, after confirming the synchronization acquisition by the control slot as shown in FIG. 9, the current status of the slave unit is confirmed, and the channel and slot used for communication are designated for the slave unit. . Next, a call signal is transmitted to the slave unit (step S74), and a response from the slave unit is waited (step S75).
[0131]
  As a result, when there is a response from the slave unit (step S75; YES), non-voice data slot allocation processing is performed (step S76). This process is shown in FIG. 16, and first, allocation of data received from an outside line to a data slot is performed (step S87). Specifically, the transmission data length in one frame is determined in consideration of the length of received data or the presence / absence of voice data transmitted / received to / from the voice terminal slave unit, and is used for transmission start timing and transmission. Determine the channel. And these information is transmitted with respect to a subunit | mobile_unit at the time of the synchronous acquisition mentioned above.
[0132]
  In this way, when communication with the slave unit becomes possible, wireless communication between the master unit 1 and the slave unit at the timing of the data slot is started (step S88), and storage processing of the received data in the memory is started. (Step S89).
[0133]
  As a result, the data received from the outside line is decoded by the modem 5, temporarily stored in the memory by the CPU 10, and then output to the transmission / reception device 6 at the timing of the data terminal transmission slot under the control of the CPU 10, and the transmission / reception is performed. Wireless transmission is performed by the device 6 to the slave unit by frequency hopping. In the slave unit, the received data is decoded by the modem of the slave unit and taken into the slave unit.
[0134]
  Next, it is determined whether or not the data transmitted from the outside line is FAX data (step S90). This is because, in the case of FAX data, transmission to the slave unit is performed, and a fax image may be set to be output by the master unit.
[0135]
  Whether or not the data is FAX data is determined based on whether or not the data fetched through the modem 5 during the above-described data type determination processing is a calling tone. Then, the CPU 10 stores the determination result in the RAM 12 or the like during the data type determination process, thereby enabling the determination.
[0136]
  As a result of the above determination, if it is not a modem (step S90; NO), rewriting the area corresponding to the modem 5 in the hardware management table and rewriting the areas of the master unit and the slave unit in the communication control table (Step S94), and the process proceeds to the communication end monitoring process (step S95).
[0137]
  As described above, wireless communication with high confidentiality and high frequency efficiency is performed by switching the hopping frequency for each frame while communicating data received from the outside line to the slave unit in units of one frame. Is called.
[0138]
  On the other hand, if the data transmitted from the outside line is FAX data (step S90; YES), whether or not to perform image output in the master unit 1 in addition to the data transmission to the slave unit as described above. A determination is made (step S91). The selection of the image output operation in the master unit is performed in advance by the operation unit of the master unit 1 and can be determined by checking an internal flag or the like. If image output in the parent device is selected (step S91; YES), it is next checked whether or not the image output block 8 is usable by an internal signal in the parent device 1 (step S92). ). As a result, when the image output block 8 can be used (step S92; YES), the CPU 10 decodes the data transmitted from the outside line by the modem 5 and stores it in the buffer 8a while storing it in the buffer 8a. The image output by is started (step S93). Thereafter, the contents of the hardware management table and the communication control table are rewritten as described above (step S94).
[0139]
  Next, processing in a case where a response from the slave unit is not obtained in step S75 shown in FIG. 15 (step S75; NO) will be described. In this case, first, it is determined whether or not a predetermined time has elapsed since the calling signal was transmitted to the slave unit (step S80). If the predetermined time has elapsed (step S80; YES), it is determined whether the data transmitted from the outside line is FAX data (step S81). If it is not FAX data (step S81; NO), the outside line A signal for rejecting the communication request is transmitted (step S79), the modem 5 is released (step S84), the external line management table is rewritten (step S85), and the process proceeds to the communication end monitoring process (step S86). If the data transmitted from the outside line is FAX data (step S81; YES), the process proceeds to a master FAX reception process (step S82). Details of this processing will be described later.
[0140]
  If the predetermined time has not elapsed (step S80; NO), it is determined whether or not transmission from the outside line has been stopped (step S83). As a result, if the transmission is not stopped (step S83; NO), the response waiting process from the slave unit is continued. If the transmission is stopped (step S83; YES), the modem 5 is continued. Is released (step S84), the external line management table is rewritten (step S85), and the process proceeds to the communication end monitoring process (step S86).
[0141]
  Next, in step S70 in FIG. 15, when all the slave units are in use (step S70; YES), or any of the slave units can be used, but in step S71, the data slot is already in use (step S70). The process of S71; YES) will be described. In this case, before rejecting the communication request from the outside line, it is determined whether or not the transmitted data is FAX data (step S77). This is because FAX data can be processed by the master unit alone even when the slave unit for data terminal is in use. The method for determining whether or not the data is FAX data is as described above. As a result, if it is not FAX data (step S77; NO), the communication request for the outside line is rejected (step S79), the modem 5 is released (step S84), and the outside line management table is rewritten (step S85). The process proceeds to the communication end monitoring process (step S86).
[0142]
  On the other hand, in the case of FAX data (step S77; YES), the process proceeds to a master FAX reception process (step S78). This process is a process that is similarly performed when a response from the slave unit is not performed within a predetermined time (step S80; YES), and details are shown in FIG. First, whether or not the image output block 8 in the parent device 1 is in use is determined based on a signal or the like in the parent device 1 (step S96). If the image output block 8 is in use (step S96; YES). Then, a FAX interrupt process to be described later is performed (step S99). If the image output block 8 can be used (step S96; NO), it is determined whether image output in the parent device is selected (step S97). If image output in the master unit is not selected (step S97; NO), a FAX interrupt process described later is performed (step S99). If it has been selected (step S97; YES), storage processing of data received from the outside line to the memory is started (step S98). Next, while performing transfer processing from the memory to the buffer 8a, image output processing by the image output block 8 is started (step S93), and the hardware management table and communication control table are rewritten (step S94). Then, the process proceeds to the communication end monitoring process (step S95).
[0143]
  As described above, in this embodiment, when there is a transmission request for FAX data from an external line, FAX reception and image output can be performed independently of the parent device even if the child device is not in a receivable state.
[0144]
  Next, the case where there is a communication request from the parent device in step S3 shown in FIG. 11 will be described (step S3; YES). In this case, the process proceeds to base unit transmission data processing (step S4), and details of this processing are shown in FIG.
[0145]
  Here, when there is a communication request from the master unit, there is an external line communication request from the master unit, or there is an extension communication request from the master unit to the slave unit. And non-voice data.
[0146]
  First, a case where there is an external line communication request by voice data from the master unit will be described. Whether the communication partner is an external line or an internal line can be determined by selecting a button (not shown) or the like provided on the handset 9 and reading a selection signal from the handset 9 by the CPU 10. . If the result of the determination is that the communication partner is an external line (step S100; YES), it is determined whether or not the communication request is from the handset 9 (step S102). This is for determining whether the data used for communication is voice data or non-voice data. As a result, in the case of a communication request from the handset 9 (step S102; YES), the external line is connected and the external line management table is rewritten (step S113). That is, the information corresponding to the handset is stored in the area 141 corresponding to the free outside line in the table. Then, a call signal for the communication partner through the outside line is created and the call signal is transmitted (step S114). Thereafter, a response from the communication partner is waited (step S115). When the handset 9 is in an on-hook state while waiting for the response (step S116; YES), as shown in FIG. The table is rewritten (step S40), and the process proceeds to the communication end monitoring process (step S41).
[0147]
  On the other hand, when there is a response from the communication partner (step S115; YES), external line communication by the handset 9 is started (step S117), and the contents of the communication control table are rewritten (step S118). Then, the process proceeds to a communication end monitoring process (step S119). In this way, an outside line call using the outside line from the base unit 1 is performed.
[0148]
  Next, processing in the case of performing external line transmission using an external line of non-voice data from the base unit 1, that is, FAX data transmission will be described. Also in this case, since the FAX data transmission is selected by the operation panel (not shown) of the base unit 1 or the like, it can be determined that the FAX data transmission is performed by reading the selection signal by the CPU 10 (step S100; YES). -Step S102; NO). Next, it is determined whether or not the modem 5 is usable by referring to the hardware management table (step S103). If the modem 5 is already in use (step S103; YES), the communication request is rejected. (Step S130), the process proceeds to a communication end monitoring process (Step S131). However, if the modem 5 can be used (step S103; NO), the modem 5 is connected to the outside line to establish a protocol (step S104). Specifically, transmission of a transmission command and reception of a reception preparation confirmation command are performed in accordance with the G3 standard.
[0149]
  Then, the external line management table is rewritten (step S105), a call signal for the communication partner is created and the call signal is transmitted (step S106). Thereafter, a response from the communication partner is awaited (step S107), but if there is no response from the communication partner even after a predetermined period of time has elapsed since the calling signal was transmitted (step S108; YES), FIG. As shown in FIG. 15, the communication request to the base unit 1 is rejected (step S79), the connected modem 5 is released (step S84), the external line management table is rewritten (step S85), and the process proceeds to the communication end monitoring process. (Step S86). Also, when a request to cancel transmission is output from the base unit side as shown in FIG. 17 (step S109; YES), the release processing of the modem 5 (step S84) as shown in FIG. A rewrite process (step S85) is performed.
[0150]
  However, as shown in FIG. 17, when there is a response from the communication partner within a predetermined period (step S107; YES), FAX transmission is started (step S110), and the hardware management table and communication control table are updated. Rewriting is performed (step S118). That is, information indicating that the connected device is a parent device is stored in the area 143 corresponding to the modem 5 in the hardware management table.
[0151]
  This FAX transmission is performed not only on the data read by the image reading block 7 of the master device but also on the data transmitted from the data terminal slave devices 40A to 40D and stored in the memory in the master device. In either case, the image data is output from the CPU 10 to the modem 5, encoded, and transmitted to the outside line. As described above, the apparatus according to the present embodiment can also be used as an ordinary FAX transmitter.
[0152]
  Next, the case where there is an extension communication request from the parent device 1 to the child device in step S100 of FIG. 17 (step S100; NO) will be described. As described above, in this case as well, the request can be determined by pressing a button on the operation panel or the like of the master unit 1, and at that time, whether the communication partner is a slave unit or whether the master unit is confident is selected by a button or the like. It is possible. When there is no communication partner and the master device is operated (step S120; NO), that is, when the master device is used like a copier, hardware such as the image reading block 7 and the image output block 8 is provided. It is determined whether or not it can be used by a signal in the main unit (step S122). If the hardware is in use (step S122; YES), the request is rejected (step S130), and the communication end monitoring process is performed. Transition is made (step S131). However, if the hardware can be used (step S122; NO), the copy operation is started (step S124), and the process proceeds to the communication end monitoring process (step S125).
[0153]
  On the other hand, when the communication partner is a slave unit (step S120; YES), the process proceeds to a base unit extension process (step S121). This process is shown in detail in FIG. 18. First, it is determined whether or not the transmission is from the handset 9 of the parent device (step S140). This is for determining whether the data to be handled is audio data or non-audio data. As a result, in the case of transmission from the handset 9 (step S140; YES), it is determined by referring to the communication control table whether the voice terminal slave units 20A to 20D are usable (step S152). If it can be used (step S152; NO), it is next determined whether or not the voice slot can be used with reference to the communication control table (step S153). If it can be used (step S153; NO). Next, it is determined by referring to the hardware management table whether or not the audio codec is usable (step S154). If the audio codec is usable, the audio codec is connected to the NCU.
[0154]
  However, if all the slave units are already in use (step S152; YES), if the voice slot is already in use (step S153; YES), or if all the voice codecs are already in use (step S152). S154; YES), as shown in FIG. 17, the request is rejected (step S130), and the process proceeds to a communication end monitoring process (step S131).
[0155]
  When the audio codec is connected to the NCU (step S155), information indicating that the connected device is a slave that can be used is stored in the area 143 corresponding to the audio codec in the hardware management table (step S155). In step S156, a call signal for the child device is generated and the call signal is transmitted (step S157).
[0156]
  Thereafter, a response from the slave unit is waited (step S158). If the handset 9 is in an on-hook state while waiting for the response (step S160; YES), the connected voice codec is released (step S161). ), The hardware management table is rewritten (step S162). However, if there is a response as to the slave unit (step S158; YES), the process proceeds to a slot allocation process for audio data (step S159). This process is the same as the process described above with reference to FIG. 13, and assigns voice slots, starts communication, and rewrites the communication control table (steps S50 to S54).
[0157]
  Next, the case where the extension communication request from the parent device is not from the handset 9 (step S140; NO) will be described. This is a case where the FAX data once stored in the parent device is transmitted to the child device later. In this case, first, it is determined by referring to the communication control table whether any of the data terminal slave units 40A to 40D is usable (step S141). Step S141; NO) Next, it is determined with reference to the communication control table whether or not the data slot is usable (Step S142). If the data slot is usable (step S142; NO), it is next determined whether or not the modem 5 is usable (step S143). If the data slot is usable (step S143; NO), The modem 5 is connected to the CPU 10 and a protocol is established with the slave unit (step S144).
[0158]
  However, if all the data terminal slaves are in use (step S141; YES), if the data slot is already in use (step S142; YES), or if the modem 5 is already in use (step S143; YES), the request is rejected as shown in FIG. 17 (step S130), and the process proceeds to the communication end monitoring process (step S131).
[0159]
  After the modem 5 is connected to the CPU 10, information indicating that the connected device is the usable slave unit is stored in the area 143 corresponding to the modem 5 in the hardware management table (step S145). A call signal is created and transmitted (step S146).
[0160]
  After this, a response from the slave unit is awaited (step S147), but if there is no response after the elapse of a predetermined period from the transmission of the calling signal (step S148; YES), or when transmission from the master unit is stopped (Step S149; YES), the connected modem 5 is released (Step S150), and the hardware management table is rewritten (Step S162).
[0161]
  However, if the response from the slave unit is within the predetermined period (step S147; YES), the process proceeds to the non-voice data slot allocation process (step S151). This process is the same as the process described above with reference to FIG. 16. The transmission data from the parent device is assigned to the data slot, wireless communication with the child device is started, and the contents of the communication control table are changed. It is to be rewritten (steps S87 to S95).
[0162]
  As described above, in the apparatus according to the present embodiment, extension communication using voice data and non-voice data between a parent device and a child device is possible.
[0163]
  Next, the case where there is a communication request from the slave unit in step S1 of FIG. 11 (step S1; YES) will be described. In this case, the process proceeds to the slave unit transmission data process (step S2). Details of this process are shown in FIG.
[0164]
  First, it is determined whether or not the communication partner requested by the slave unit is a slave unit (step S170). The information related to the communication partner is information included in the response data 125 in the response slot 120 shown in FIG. 9, and the master unit obtains this information at the time of synchronization acquisition and performs the determination. As a result, when the communication partner is not a slave (step S170; NO), it is determined whether or not the transmission source is a voice terminal slave (step S175). This is determined by the transmission side ID 123 of the response slot 120 shown in FIG.
[0165]
  As a result, when the transmission slave unit is a voice terminal slave unit (step S175; YES), it is determined by referring to the hardware management table whether the voice codec is usable (step S176). If such an audio codec is usable (step S176; NO), it is next determined with reference to the communication control table whether an audio slot is available (step S177). If the voice slot is usable (step S177; NO), it is determined whether or not the communication partner requested by the transmission source slave unit is an external line (step S178). This is also determined based on information included in the response data 125. As a result, when the communication partner is not an external line (step S178; NO), an extension call is made with the base unit, so whether or not the handset 9 of the base unit is in use is determined based on a hook signal or the like. (Step S179). If the handset 9 can be used (step S179; NO), the parent device connects the voice codec (3a, 3b) of the parent device and the handset to the CPU 10 of the parent device (step S180).
[0166]
  On the other hand, if the communication partner requested by the slave unit is an external line (step S178; YES), the voice codec of the base unit is connected to the external line (step S189), and the external line management table is rewritten (step S190).
[0167]
  However, in the processing so far, all the audio codecs are already in use (step S176; YES), the audio slot is already in use (step S177; YES), or the handset 9 is already in use. In this case (step S179; YES), since the extension call cannot be made between the slave unit and the master unit, a request rejection signal is transmitted to the slave unit as shown in FIG. 17 (step S130), and the communication end monitoring process is performed. (Step S131).
[0168]
  As described above, when the audio codec of the master unit is connected to either the external line or the handset, the area corresponding to the audio codec in the hardware management table is rewritten (step S181), and the request is made to the slave unit. A permission signal is transmitted (step S182). This information is transmitted to the slave unit as communication processing data 135 in the communication processing slot 130 shown in FIG. Then, the voice slot length is determined in consideration of the channel used for communication with the slave unit and the presence of non-voice data, the voice slot is assigned for communication with the slave unit (step S183), and the communication control table is rewritten (step S183). Step S184). That is, information indicating the slave unit is stored in the area 145 of the communication partner terminal of the master unit, voice is stored in the slot, and information indicating the selected channel is stored in the channel. In addition, information indicating the master unit is stored in the area 145 of the communication partner terminal of the slave unit, voice is stored in the slot, and information indicating the same channel is stored in the channel.
[0169]
  Then, communication using the voice slot is started (step S185), and the process proceeds to a handset voice data call process (step S186).
[0170]
  The details of this process are shown in FIG. 20. First, when the communication partner of the slave unit is not an external line (step S210; NO), the master unit has received a call signal transmitted from the slave unit. It is determined whether or not (step S213). As a result, if the call signal from the slave unit can be received within a predetermined period (step S213; YES), the call signal is transmitted to the handset 9 to call the handset 9 (step S215), and the response of the handset 9 (Step S216), and if there is a response from the handset 9 (step S216; YES), an extension call between the handset 9 and the slave unit is started (step S218), and the process proceeds to a communication end monitoring process (step S218). Step S219).
[0171]
  On the other hand, in a response waiting state from the handset 9 (step S216), when a communication end request is made from the transmission side slave unit (step S217; YES), a communication end permission signal is transmitted to the slave unit. (Step S221), the connected audio codec is released (step S222), the audio slot is also released (step S223), the hardware management table and the communication control table are rewritten (step S224), and the communication end monitoring is performed. The process proceeds to processing (step S219).
[0172]
  When the calling signal from the slave unit to the master unit is not received within a predetermined period (step S213; NO to step S214; YES), the connected voice codec is released (step S225), and the voice slot (Step S226), the hardware management table and the communication control table are rewritten (step S227), a request rejection signal is transmitted to the slave unit (step S228), and the process proceeds to a communication end monitoring process (step S228). S219).
[0173]
  Further, after the wireless communication with the slave unit is started, if the determination result of the communication partner requested by the slave unit is an external line (step S210; YES), a slave unit external line process is performed (step S211), The process proceeds to the communication end monitoring process (step S212). This slave unit outside line processing is for performing a normal outside line call through a voice codec connected to the outside line.
[0174]
  Next, a case will be described in which the slave unit that is the transmission source is the data terminal slave unit in step S175 of FIG. 19 (step S175; NO). In this case, it is first determined whether or not the modem 5 can be used with reference to the hardware management table (step S191). If it can be used (step S191; NO), the data slot is used. Whether it is possible is determined by referring to the communication control table (step S192). If the data slot is usable (step S192; NO), it is determined whether or not the communication partner requested by the slave unit is only an external line (step S193). And so on (step S193; NO), it is determined based on an internal signal or the like whether or not hardware such as the image reading block 7 or the image output block 8 of the master unit used for the image output or the like can be used. (Step S194). As a result, when the hardware is usable (step S194; NO), the modem 5 is connected to the CPU 10 (step S195).
[0175]
  If the requested communication partner is not only the parent device (step S196; NO), or if the requested communication partner is only an external line in step S193 (step S193; YES), the modem 5 is connected to the external line to establish a protocol. At the same time (step S199), the outside line management table is rewritten (step S200).
[0176]
  However, if the modem 5 is already in use (step S191; YES), the data slot is already in use (step S192; YES), or the base unit hardware is already in use in the processing so far. In this case (step S194; YES), as shown in FIG. 17, a signal for rejecting the request is transmitted to the slave unit (step S130), and the process proceeds to the communication end monitoring process (step S131).
[0177]
  After the connection destination of the modem 5 is determined as described above, the contents of the area corresponding to the modem 5 in the hardware management table are rewritten (step S201), and a communication request permission signal is transmitted to the slave unit. (Step S202). Then, the data slot is allocated for wireless communication with the slave unit (step S203), the communication control table is rewritten (step S204), and the process proceeds to the slave unit non-voice data call processing (step S205).
[0178]
  The details of this process are shown in FIG. 21. First, it is determined whether or not the communication partner terminal requested by the slave unit is only an external line (step S230). As a result, when image output or the like is performed not only on the outside line but also on the parent device (step S230; NO), it is determined whether data is output or input is performed on the parent device (step S230). S231). This information is transmitted from the slave unit to the master unit as information in the response data of the response slot 120 shown in FIG. As a result of the determination, when outputting to the parent device (step S231; output), storage processing of data transmitted from the child device and received by the parent device to the memory in the parent device is started (step S232), and the image is displayed. Image output by the output block 8 is started (step S233). On the other hand, when inputting data in the parent device (step S231; input), image reading is started by the image reading block 7 (step S236), and processing for storing the read data in the memory in the parent device is started. (Step S237). Next, a process of transmitting the data stored in the memory to the slave unit using the data slot is started (step S238).
[0179]
  After performing the data output or input start processing in the master unit in this way, it is determined whether or not the request communication partner from the slave unit is only the master unit (step S234), and the request communication partner is only the master unit. If not (step S234; NO), or if the requested communication partner is only an outside line in step S230 (step S230; YES), the slave unit outside line processing is started (step S239). This slave unit external line processing performs normal FAX communication or data communication via the modem 5 connected to the external line.
[0180]
  Note that, after the above process, the process of transitioning to the communication end monitoring process (step S235) is the same as in the other communication processes described above.
[0181]
  As described above, according to the apparatus of the present embodiment, extension communication between a slave unit and a master unit or an external line communication according to a request from a slave unit is possible, and these communications are performed on both voice data and non-voice data. This is possible.
[0182]
  Next, the case where the communication request partner from the slave unit is another slave unit in step S129 of FIG. 19 (step S170; YES) will be described. In this case, the process proceeds to the slave unit-slave unit communication process (step S171). Details of this processing are shown in FIG. 22. First, referring to the synchronization acquisition information area 148 of the communication control table, it is determined whether or not synchronization is established between the slave unit and the master unit of the communication partner. Determination is made (step S240). This is because when the extension communication between the slave unit and the slave unit is started, a normal response cannot be obtained from these slave units even if the synchronization acquisition process is performed in the master unit. If synchronization is established (step S240; YES), it is next determined by referring to the communication control table whether or not the communication partner slave unit is usable (step S241). In such a case (step S241; NO), it is determined by referring to the communication control table whether there is an unused channel (step S242). This is because the communication between the slave unit and the slave unit is possible in order to enable communication between the slave unit and the slave unit even when a voice slot and a non-voice slot of a certain channel are used between the master unit and the slave unit. Is used to select a channel that is not used for communication between the parent device and the child device. If the result of determination is that there is an empty channel, that channel is assigned to communication between the slave unit and the slave unit (step S243), and the channel information area 147 for both slave units in the communication control table is rewritten (step S244).
[0183]
  If the slave unit that is the communication partner is not synchronized (step S240; NO), if the slave unit is already in use (step S241; YES), or if there is no available channel ( Step S242; YES), a request rejection signal for the slave unit is transmitted as shown in FIG. 17 (step S130), and the process proceeds to a communication end monitoring process (step S131).
[0184]
  After channel assignment is completed, a communication request permission signal is transmitted to the slave unit together with the channel information (step S245), and the master unit recognizes the start of communication between the slave unit and the slave unit (step S246). ).
[0185]
  On the other hand, the slave unit that has received the communication request permission signal transmits a communication request to another slave unit that is a communication partner, and starts communication with each other after obtaining communication permission from the slave unit. Although this communication is also performed by a frequency hopping method, the frame structure and slot structure used may be the same as those used between the parent machine and the child machine as described above, or may be different structures. However, by using the frame and slot having the above-described structure, wireless communication in which voice data and non-voice data are mixed can be performed between the slave units.
[0186]
  Further, after the above process, the process proceeds to the communication end monitoring process (step S247), but the communication permission cannot be received from the other slave unit as a result of the transmission of the communication request from the slave unit to the other slave unit. In this case, a communication end request is transmitted from the slave unit to the master unit, and when this is recognized in step S63 shown in FIG. 14, the master unit transmits a communication end permission signal to the slave unit. (Step S64) The slot and channel are released, the table is rewritten, etc. (Step S65 to Step S66).
[0187]
  A communication end request in the communication between the slave unit and the slave unit is transmitted according to the priority order of the slave units registered in advance in the master unit. That is, if the priority order of the slave unit 20A is higher than the priority order of the slave unit 20B, the slave unit 20A first transmits a communication end request signal to the master unit. However, since the end permission signal is transmitted from the master unit in response to the end request signal transmitted by the slave unit A, and the slave unit B does not know that the slave unit A has received the permission signal, Regardless of whether or not the machine A has received the communication end permission signal, it transmits a communication end request signal to the parent machine. Then, transmission / reception of these signals is continued until the master unit finally recognizes the communication end request signal and both the slave unit A and the slave unit B recognize.
[0188]
  This communication between the slave unit and the slave unit is performed between the voice terminal slave units or between the data terminal slave units, and is performed in parallel between the voice terminal slave unit and the data terminal slave unit. Simultaneous communication is possible.
[0189]
  As described above, according to the apparatus of the present embodiment, wireless communication using the frequency hopping method can be performed between the child device and the child device while performing wireless communication using the frequency hopping method between the parent device and the child device.
[0190]
  As described above in detail, according to the apparatus of the present embodiment, various types of communication are possible. However, in principle, when one piece of hardware is used, the hardware is used for other processing. Cannot be used.
[0191]
  However, if a fax data transmission request is issued from an external line while the master unit 1 is performing print output in response to an extension communication request from the data terminal slave units 40A to 40D, the FAX data transmission side waits. Will be in a state, and will be in a time-out state, and normal reception will not be possible.
[0192]
  Therefore, in this embodiment, in order to avoid such a situation, a data transmission interruption request is transmitted to the data terminal slave unit that is transmitting the print output data, and FAX data from the outside line is transmitted. It was configured to perform image output based on. Specific processing will be described below.
[0193]
  First, during a print output, when there is a communication request from an outside line as shown in step S5 of FIG. 11 (step S5; YES), based on the communication control table, communication with the current data terminal slave unit is performed. It is determined whether or not communication is being performed (step S300). In this case, since the print is being output, communication between the master unit 1 and the data terminal slave unit is performed (step S300; YES). Next, the data requested for communication from the outside line is FAX data. Whether or not (step S301). If this data is FAX data (step S301; YES), the process proceeds to FAX interrupt processing (step S302).
[0194]
  Details of this processing are described in FIG. 23. First, an interruption signal for interrupting transmission of print data is transmitted to the slave unit (step S320). This transmission is performed using the synchronization acquisition frame at the above-described synchronization acquisition timing. Accordingly, since no new data is transmitted from the slave unit, the master unit 1 performs an interruption process to interrupt the current print operation (step S321). For example, the interruption process may be performed by completing print output for one page and storing a page to be resumed, or printing all data currently stored in the print buffer. May be.
[0195]
  Next, in the state where the interruption process is completed and the image output block 8 is usable, the modem 5 which has been used for communication with the slave unit is connected to the external line for which communication has been requested, and the protocol is established. Then, the contents of each table are rewritten (step S322). Then, communication with the outside line is started, storage of FAX data in the memory is started (step S323), and print output is started (step S324). As a result, FAX data from the outside line can be normally received and output even during printing of data from the slave unit.
[0196]
  Next, after printing output is started as described above, a FAX interrupt mode flag is set (step S325), and the process proceeds to communication end processing (step S326).
[0197]
  This process is shown in FIG. 14 as described above. If it is determined in step S304 that the FAX interrupt mode is selected (step S304; YES), it is determined whether or not the output of FAX data is completed. (Step S305). When the output of FAX data is completed (step S305; YES), the FAX interrupt mode flag is cleared and a restart signal is transmitted to the slave unit that has transmitted the interruption signal as described above. The user is prompted to resume data transmission (step S306). When this restart signal is transmitted, the restart page information may be transmitted as described above. Then, it waits for a response from the slave unit (step S307). If there is no response (step S307; NO), the image output block 8 and the data slot are released (step S65), and each table is rewritten. (Step S66), the process ends.
[0198]
  However, if there is a response from the slave unit (step S307; YES), resumption processing such as connection of the modem 5 to the CPU 10, establishment of the protocol, and slot allocation as described above is performed (step S307). In step S308, as shown in FIG. 21, storage of data from the slave unit in the memory is started (step S232), and printing processing based on the data is resumed (step S233).
[0199]
  As described above, according to the apparatus of the present embodiment, even when there is a request for transmission of FAX data from an external line during print output based on data from the data terminal slave unit, data transmission to the data terminal slave unit is performed. Since the image output block 8 is switched, the FAX data can be normally received.
[0200]
  Moreover, since the synchronization between the master unit and the slave unit is maintained by the above-described synchronization acquisition process even during printing of the FAX data, communication with the slave unit is resumed after the print output of the FAX data is completed. Even in the case of starting, there is no loss of synchronization, and data output from the slave unit can be resumed normally.
[0201]
  As described above, in the apparatus according to the present embodiment, FAX data can always be output almost in real time, so that the number of reception buffers can be reduced.
[0202]
  As described above, according to the apparatus of the present embodiment, both voice data and non-voice data can be transmitted and received in one frame, so that data from other slave units can be transmitted during an external line call by the slave unit. Efficient communication is possible, such as printing out by the master unit or transmitting data from the slave unit via an external line. And since this communication is performed by the frequency hopping method, the confidentiality of communication and the frequency use efficiency are improved.
[0203]
  Further, the apparatus of this embodiment can be used as a facsimile apparatus and a printer apparatus, and can receive and output FAX data from an outside line normally even while printing data from a slave unit. A good use environment can be provided to the user.
[0204]
  In this embodiment, the communication control table is managed so that a communication request from a child device other than the child device that transmitted the interruption signal is rejected on the parent device side. However, the interruption signal is transmitted. At this time, a busy signal may be transmitted to other slave units. By configuring in this way, it is possible to grasp the current operation status of the parent device by the other child device itself.
[0205]
  (Second Embodiment) Next, a second embodiment of the present invention will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected to a common location with 1st Embodiment, and description is abbreviate | omitted.
[0206]
  This embodiment is different from the first embodiment in that frequency hopping is stopped for both the parent device and the child device in the FAX interrupt processing.
[0207]
  Hereinafter, the FAX interrupt process of this embodiment will be described. First, as shown in FIG. 24, when the FAX interrupt process is started, an interruption signal is transmitted to the slave unit (step S320). Then, it is determined using the communication control table whether or not communication between the slave unit other than the slave unit that has transmitted the interruption signal and the master unit 1 is performed (step S330), and other than the slave unit that has transmitted the suspension signal. If communication with the slave unit is not performed (step S330; NO), a frequency hopping stop signal is further transmitted to the slave unit that has transmitted the interruption signal. This signal is also performed using the synchronization acquisition frame. Then, the base unit itself stops frequency hopping (step S332).
[0208]
  Next, as in the first embodiment, an interruption process is performed in order to interrupt the current printing operation (step S321). For example, the print output for one page may be completed and the page to be resumed may be stored, or all data currently stored in the print buffer may be printed out.
[0209]
  Then, in the state where the interruption process is completed and the image output block 8 is usable, the modem 5 that has been used for communication with the slave unit is connected to the external line that has been requested to communicate, and the protocol is established. The contents of each table are rewritten (step S322). Then, communication with the outside line is started, storage of FAX data in the memory is started (step S323), and print output is started (step S324). As a result, FAX data from the outside line can be normally received and output even during printing of data from the slave unit.
[0210]
  Next, after printing output is started as described above, a FAX interrupt mode flag is set (step S325), and the process proceeds to communication end processing (step S326).
[0211]
  This process is shown in FIG. 25 as described above. When it is determined in step S304 that the FAX interrupt mode is selected (step S304; YES), it is determined whether or not the output of FAX data is completed. (Step S305). When the output of FAX data is completed (step S305; YES), the FAX interrupt mode flag is cleared and a restart signal is transmitted to the slave unit that has transmitted the interruption signal as described above. The user is prompted to resume data transmission (step S306). When this restart signal is transmitted, the restart page information may be transmitted as described above. Then, a frequency hopping start signal is transmitted to the slave unit (step S333), and the master unit also starts frequency hopping (step S334).
[0212]
  As a result, since the master unit and the slave unit are synchronized again, the master unit waits for a response from the slave unit (step S307), and when there is no response (step S307; NO) Then, the image output block 8 and the data slot are released (step S65), each table is rewritten (step S66), and the process is terminated.
[0213]
  However, if there is a response from the slave unit (step S307; YES), resumption processing such as connection of the modem 5 to the CPU 10, establishment of the protocol, and slot allocation as described above is performed (step S307). In step S308, as shown in FIG. 21, storage of data from the slave unit in the memory is started (step S232), and printing processing based on the data is resumed (step S233).
[0214]
  As described above, according to the present embodiment, since both the base unit and the slave unit stop frequency hopping when communication is interrupted, there is no possibility that the synchronization between the master unit and the slave unit is lost, and FAX data from the outside line is lost. Immediately after the completion of the output, the output from the slave unit can be resumed. Further, power saving can be achieved by temporarily stopping frequency hopping. Further, since the master unit and the slave unit are stopped at the same frequency, it is not necessary to always perform the synchronization acquisition process as in the first embodiment.
[0215]
  In this embodiment, as shown in step S330 of FIG. 24, when communication is performed between the master unit and the voice terminal slave unit, the frequency hopping is not stopped. During communication with the voice terminal, hopping may be stopped only for the data slot and not used.
[0216]
  In addition, when communication is performed between the voice terminal slave unit and the master unit, the master unit outputs a hop stop signal every time or when no other slave unit is using the channel where hopping is stopped. You may do it. Thereby, when the transmission of the restart signal to the child device cannot be performed by the parent device for a long time, the child device receiving the interruption signal is in the state of the parent device, for example, outputting long-time FAX data. It is possible to grasp whether there is an error or some kind of error.
[0217]
  (Third Embodiment) Next, a third embodiment of the present invention will be described with reference to FIG. In addition, the same code | symbol is attached | subjected to a common location with 1st Embodiment and 2nd Embodiment, and description is abbreviate | omitted.
[0218]
  This embodiment is the same as the second embodiment in that the frequency hopping is stopped for both the master unit and the slave unit in the FAX interrupt processing, but the channel is set when there is no response from the slave unit when restarting. Switching is different from the second embodiment.
[0219]
  Hereinafter, the restart process from the FAX interrupt process of this embodiment will be described. First, as shown in FIG. 26, when it is determined in step S304 that the FAX interrupt mode is set (step S304; YES), it is determined whether or not the output of FAX data is completed (step S305). When the output of FAX data is completed (step S305; YES), the FAX interrupt mode flag is cleared and a restart signal is transmitted to the slave unit that has transmitted the interruption signal as described above. The user is prompted to resume data transmission (step S306). When this restart signal is transmitted, the restart page information may be transmitted as described above. Then, a frequency hopping start signal is transmitted to the slave unit (step S333), and the master unit also starts frequency hopping (step S334).
[0220]
  As a result, since the master unit and the slave unit are synchronized again, the master unit waits for a response from the slave unit (step S307).
[0221]
  If there is no response (step S307; NO), within a predetermined time (step S335; NO), the channels are sequentially switched (step S336), and the above-described restart signal transmission and the like are repeated.
[0222]
  However, if no response is obtained after the predetermined time has elapsed (step S335; YES), the image output block 8 and the data slot are released (step S65), each table is rewritten (step S66), and the process is performed. finish.
[0223]
  On the other hand, if there is a response from the slave unit (step S307; YES), resumption processing such as connection of the modem 5 to the CPU 10, establishment of the protocol, and slot assignment as described above is performed (step S307). In step S308, as shown in FIG. 21, storage of data from the slave unit in the memory is started (step S232), and printing processing based on the data is resumed (step S233).
[0224]
  As described above, according to the present embodiment, when there is no response from the slave unit at the time of restart, the channel is switched, so even if communication with the slave unit is interrupted at the time of restart, it is ensured. The communication with the slave unit can be resumed.
[0225]
  Similarly to the second embodiment, since both the base unit and the slave unit stop frequency hopping when communication is interrupted, there is no possibility that the synchronization between the master unit and the slave unit will be lost, and the FAX data from the outside line will not be lost. Immediately after the output, the output from the slave unit can be resumed. Further, power saving can be achieved by temporarily stopping frequency hopping. Further, since the master unit and the slave unit are stopped at the same frequency, it is not necessary to always perform the synchronization acquisition process as in the first embodiment.
[0226]
  (Fourth Embodiment) Next, a fourth embodiment of the present invention will be described with reference to FIG. In addition, the same code | symbol is attached | subjected to a common location with 1st Embodiment thru | or 3rd Embodiment, and description is abbreviate | omitted.
[0227]
  This embodiment is the same as the second embodiment in that frequency hopping is stopped for both the master unit and the slave unit in the FAX interrupt processing, and the channel is switched when there is no response from the slave unit at the time of restart. However, the third embodiment is similar to the third embodiment except that a standby signal is transmitted to the slave unit during output of FAX data from the outside line, and the channel is switched according to the presence or absence of a response from the standby signal. Different from the embodiment.
[0228]
  Hereinafter, the process from the transition to the FAX interrupt process to the restart process according to the present embodiment will be described. First, as shown in FIG. 27, when it is determined in step S304 that the FAX interrupt mode is set (step S304; YES), it is determined whether or not the output of FAX data is completed (step S305).
[0229]
  Then, when the output of FAX data is not completed (step S305; NO), a standby signal is transmitted to the slave unit that has transmitted the interruption signal (step S337). In response to the standby signal, a response signal is transmitted from the slave unit. Therefore, by determining whether or not there is a response from the slave unit (step S338), It can be seen whether or not the communication is interrupted. Therefore, if there is a response (step S338; YES), it is assumed that no interference has occurred and transmission of the standby signal is continued as it is on the same channel. However, if there is no response (step S338; NO), it is determined that interference has occurred, switching to the next channel (step S339), and a standby signal is transmitted again. This is repeated until there is a response. On the other hand, if the standby signal from the master unit cannot be detected for a predetermined time, the slave unit moves to the next channel and stands by.
[0230]
  Next, when the output of FAX data is completed (step S305; YES), the same processing as in the third embodiment is performed.
[0231]
  As described above, according to the present embodiment, during output of FAX data from an external line, a standby signal is transmitted from the parent device to the child device, and the channel is switched according to the presence or absence of the response. Therefore, it is possible to smoothly resume communication between the parent device and the child device.
[0232]
  Similarly to the third embodiment, when there is no response from the slave unit at the time of restart, the channel is switched. Therefore, even if communication with the slave unit is interrupted at the time of restart, it is ensured. Communication with the slave unit can be resumed.
[0233]
  In each of the above-described embodiments, the data terminal slave unit has been described as having both the data generation unit and the wireless transmission / reception unit. However, the present invention is not limited to this, and the slave unit includes A configuration in which wireless transmission / reception means and data input means are provided and the slave unit and external data generation means can be connected may be employed.
[0234]
[0235]
[0236]
[0237]
[0238]
【The invention's effect】
  Claim1According to the communication device described in the above, when a restart request is transmitted to the slave unit, and there is no response from the slave unit, the restart frequency is changed and the restart request is transmitted again. Even in the case where there is a communication interruption or the like between the parent device and the child device, normal communication can be resumed with a different frequency.
[0239]
  Claim2According to the communication device described in (1), since the restart frequency is changed based on a finite number of restart frequencies, the storage area for the restart frequency can be reduced.
[0240]
  Claim3According to the communication device described in the above, not only non-voice data but also voice data is transmitted / received via the external communication line and the wireless communication line, and wireless transmission / reception between the master unit and the slave unit is performed with the non-voice data. Since voice data is wirelessly transmitted and received by frequency hopping using time division processing, it is possible to perform appropriate wireless communication according to the nature of the data even when non-voice data and voice data are mixed, and the efficiency of the communication device Can be used.
[Brief description of the drawings]
FIG. 1 is a block diagram of a communication apparatus according to a first embodiment of the present invention, where (A) is a block diagram showing a configuration of a master unit, (B) is a block diagram showing a configuration of a slave unit for a voice terminal, (C) is a block diagram showing the configuration of the data terminal slave unit.
FIG. 2 is a block diagram showing an overall configuration of a communication apparatus according to the first embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration of transmission / reception measures provided in the parent device and the child device of the communication device according to the first embodiment of the present invention.
4 is a graph showing an example of hop frequency switching by the transmission / reception apparatus of FIG. 3; FIG.
FIG. 5 is an explanatory diagram of a hopping frequency table used in the transmission / reception apparatus of FIG. 3;
6 is a configuration diagram of a frame used in the communication apparatus of FIG. 1;
7 is a configuration diagram of a voice terminal slot and a data terminal slot in the frame of FIG. 1; FIG.
FIG. 8 is a timing chart showing synchronization acquisition processing performed in the communication apparatus of FIG. 1;
FIG. 9 is a configuration diagram of a synchronization acquisition slot used in the synchronization acquisition process shown in FIG. 8;
10 is an explanatory diagram of a table managed by the parent device in the communication apparatus of FIG. 1, (A) is an external line management table, (B) is a hardware management table, and (C) is an explanatory diagram of a communication control table. It is.
11 is a flowchart showing communication processing in the communication apparatus of FIG. 1;.
12 is a flowchart showing voice data call processing in the communication apparatus of FIG. 1; FIG.
13 is a flowchart showing audio data slot assignment processing in the communication apparatus of FIG. 1; FIG.
14 is a flowchart showing a communication end monitoring process in the communication apparatus of FIG. 1. FIG.
FIG. 15 is a flowchart showing non-voice data call processing in the communication apparatus of FIG. 1;
16 is a flowchart showing non-voice data slot allocation processing and parent device FAX reception processing in the communication apparatus of FIG. 1; FIG.
17 is a flowchart showing parent device transmission data processing in the communication apparatus of FIG. 1;
FIG. 18 is a flowchart showing base unit extension processing in the communication apparatus of FIG. 1;
FIG. 19 is a flowchart showing handset transmission data processing in the communication apparatus of FIG. 1;
20 is a flowchart showing call processing for handset voice data in the communication apparatus of FIG. 1;
FIG. 21 is a flowchart showing call processing for slave unit non-voice data in the communication apparatus of FIG. 1;
22 is a flowchart showing a slave unit-slave unit communication process in the communication apparatus of FIG. 1; FIG.
23 is a flowchart showing a FAX interrupt process in the communication apparatus of FIG.
FIG. 24 is a flowchart showing a FAX interrupt process in the second embodiment of the present invention.
FIG. 25 is a flowchart illustrating a restart process after a FAX interrupt process according to the second embodiment of the present invention.
FIG. 26 is a flowchart illustrating a restart process after a FAX interrupt process according to the third embodiment of the present invention.
FIG. 27 is a flowchart illustrating a restart process after a FAX interrupt process according to the fourth embodiment of the present invention.
FIG. 28 is a block diagram showing a configuration of a transmission / reception apparatus according to a conventional frequency hopping method.
[Explanation of symbols]
  1 ... Master unit
  2 ... NCU
  3a, 3b ... voice codec
  5. Modem
  6 ... Transmitter / receiver
  7: Image reading block
  8. Image output block
  9 ... Handset
  10 ... CPU
  11 ... ROM
  12 ... RAM
  20A-20D ... Slave unit for voice terminal
  21A ... Microphone
  22A ... Speaker
  24A ... Audio codec
  25A ... Transmitter / receiver
  26A ... Antenna
  27A ... CPU
  40A to 40D ... Slave unit for data terminal
  41A ... display device
  42A ... CPU
  43A ... ROM
  44A ... RAM
  45A ... modem
  46A ... Transmitter / receiver
  47A ... Antenna

Claims (3)

A communication device comprising: a master unit connected to at least one external communication line; and at least one slave unit that generates at least one non-voice data connected to the radio communication line by a frequency hopping method with the master unit,
The master unit transmits and receives data according to the data type determined by the external line transmission / reception unit for transmitting / receiving data through the external communication line, the data type determination unit for determining the type of data to be transmitted / received, and the data type determination unit. Data conversion means for converting to a format that can be handled on either the external communication line side or the apparatus internal side, and base unit side wireless transmission / reception means for wirelessly transmitting / receiving at least non-voice data to / from the slave unit by a frequency hopping method External image formation data which is image formation data received by the external line transmission / reception means via the external communication line, or image formation data transmitted from the slave unit and received by the wireless transmission / reception means via the wireless communication line And image forming means for visualizing at least one of the slave unit image formation data on a recording medium and the slave unit. When the external image formation data is received from the external communication line during image formation by the image forming means based on the slave image formation data, an image formation data transmission interruption request to the slave is output, An image formation control means for performing image formation by the image formation means based on the external image formation data received from an external communication line, and causing the base unit side wireless transmission / reception means to transmit the interruption request to the slave unit Wireless communication control means,
The slave unit wirelessly transmits and receives at least non-voice data at a timing synchronized with the master unit by a frequency hopping method between at least data input means for inputting non-voice data and the master unit. In a communication apparatus provided with a machine-side wireless transmission / reception means,
When the image formation based on the external image formation data received from the external communication line is completed, the image formation control means outputs an image formation data transmission restart request to the slave unit, and the wireless communication control means , After transmitting the interruption request to the slave unit, the base unit side wireless transmission / reception unit and the slave unit side wireless transmission / reception unit stop frequency hopping and transmit the restart request to the slave unit. After that, the frequency hopping is resumed, an image formation restart request based on the slave unit image formation data transmitted from the slave unit is output to the image formation control means, and the slave unit responds to the restart request. If there is no response, the communication apparatus is characterized in that the restart frequency is changed and the restart request is transmitted again. The communication apparatus according to claim 1 , wherein the wireless communication control unit includes a finite number of the resume frequencies, and sequentially switches and transmits the finite number of resume frequencies. A communication device comprising: a master unit connected to at least one external communication line; and at least one slave unit that generates at least one non-voice data connected to the radio communication line by a frequency hopping method with the master unit,
The master unit transmits and receives data according to the data type determined by the external line transmission / reception unit for transmitting / receiving data through the external communication line, the data type determination unit for determining the type of data to be transmitted / received, and the data type determination unit. Data conversion means for converting to a format that can be handled on either the external communication line side or the apparatus internal side, and base unit side wireless transmission / reception means for wirelessly transmitting / receiving at least non-voice data to / from the slave unit by a frequency hopping method External image formation data which is image formation data received by the external line transmission / reception means via the external communication line, or image formation data transmitted from the slave unit and received by the wireless transmission / reception means via the wireless communication line And image forming means for visualizing at least one of the slave unit image formation data on a recording medium and the slave unit. When the external image formation data is received from the external communication line during image formation by the image forming means based on the slave image formation data, an image formation data transmission interruption request to the slave is output, An image formation control means for performing image formation by the image formation means based on the external image formation data received from an external communication line, and causing the base unit side wireless transmission / reception means to transmit the interruption request to the slave unit Wireless communication control means,
The slave unit wirelessly transmits and receives at least non-voice data at a timing synchronized with the master unit by a frequency hopping method between at least data input means for inputting non-voice data and the master unit. In a communication apparatus provided with a machine-side wireless transmission / reception means,
At least one slave unit that handles voice data connected to a wireless communication line is further provided,
The external line transmission / reception means includes means for transmitting / receiving voice data and non-voice data through the external communication line,
As the base unit side wireless transmission / reception means, both the non-voice data and the voice data are wirelessly transmitted / received by the frequency hopping method between the slave unit handling the non-voice data and the slave unit handling the voice data by time division processing. With means,
Further comprising: a master-side slot allocation control unit that divides one frame, which is one unit of the radio transmission / reception, into a slot for voice and a slot for non-voice, and allocates the slot according to the type of the data;
As the slave unit side wireless transmission / reception means, at least one of the voice data and non-voice data is synchronized with the master unit or another slave unit in synchronization with the radio transmission / reception timing of the master unit or another slave unit. Means for wireless transmission and reception by frequency hopping method by time division processing,
Further comprising a handset side slot assignment control means for assigning the slot according to the type of the data;
A communication device.

Images