JP6080194B2 - COMMUNICATION DEVICE, COMMUNICATION METHOD, AND PROGRAM - Google Patents

Description

  The present invention relates to a communication device, a communication method, and a program that enable high-speed startup.

  There are communication devices that wirelessly transmit and receive audio via an emergency / emergency communication network, such as fire fighting radio and police radio. Recent emergency / emergency communication devices not only establish voice calls with others, but also have various applications, change various information settings for wireless communication in the communication devices, It can also send and receive large volumes of moving image data, and manage and edit data.

  Here, the communication apparatus having such a function is equipped with a CPU (Central Processing Unit) as in a general computer. In general, a device equipped with a CPU starts up an OS (Operating System) program based on an operation of the user, and the CPU controls various functions of the device. It is a mechanism that operates as a control unit that automatically controls.

  In addition, in a device that operates based on the OS as described above, there is a demand for shortening as much time as possible until the OS is started and various applications can be used after the device is turned on. In response to such a request, for example, by providing a rich OS program (full spec OS) and a small OS program (function limiting OS), only the function that the user intends to use at the time of OS startup is urgently required. An OS startup method for shifting to an executable state is disclosed (Patent Document 1).

JP 2011-60225 A

  However, a communication device that operates based on the OS program as described above may be responsible for control of a communication function (voice call function) by a CPU that operates based on the OS program. Such a communication apparatus can use the voice call function only after starting an OS program and starting a predetermined application program operating on the OS. Therefore, in the case where it becomes necessary to restart the emergency / emergency wireless device as described above, the period from when the communication device is turned on until the startup of the OS program is completed (usually several tens of seconds) However, when an emergency wireless communication is required, a voice call cannot be immediately executed.

  Further, in the OS activation method described in Patent Document 1, only a function that a user intends to use is provided at a high speed by providing a small OS program. However, even with a small OS program with limited functions, the startup time is shortened, but it is assumed that it takes some time before the startup is actually completed. On the other hand, there is a demand for a communication device used for emergency as described above that does not want to cause even a short time when the voice call function cannot be used. Therefore, in the invention described in Patent Document 1, there is a problem that the needs required in the communication device used for emergency radio cannot be sufficiently answered.

  Therefore, an object of the present invention is to provide a communication device, a communication method, and a program that solve the above-described problems.

The present invention has been made to solve the above-described problems, and receives a first control unit for controlling a predetermined functional unit in the own apparatus based on an operating system program, and control by activation of the operating system program. The second control unit that controls a communication unit that performs predetermined communication with an external device, between the communication unit and the first control unit, and between the communication unit and the second control unit. A signal switching unit that switches connection, and the first control unit outputs a startup completion signal when the operating system program completes startup, and the second control unit outputs the startup completion signal. A first switching instruction signal is output to the signal switching unit when the signal is input, and the signal switching unit is connected between the communication unit and the first control unit when the first switching instruction signal is input. As well as connecting a communication device to separate between said second control unit and the communication unit. The second control unit may be configured by an analog circuit or a digital circuit that does not require a program. The second control unit may continue the control of the communication unit when there is an input of a signal from the communication unit even after outputting the first switching instruction signal to the signal switching unit. The first control unit outputs an operation stop signal when a shutdown signal for shutting down its own device is input by a user operation, and the second control unit outputs the operation stop signal when the operation stop signal is input. When the second switching instruction signal is output to the signal switching unit, and the signal switching unit receives the second switching instruction signal, the control source of the communication unit is transferred from the first control unit to the second control unit. You may switch.

According to the present invention, the second control unit controls a communication unit that performs predetermined communication with an external device without being controlled by the activation of the operating system program. Based on a predetermined function unit in its own device , the signal switching unit switches between the communication unit and the first control unit, and the connection between the communication unit and the second control unit, The first control unit outputs a startup completion signal when the operating system program completes startup, and the second control unit outputs the startup signal to the signal switching unit when the startup completion signal is input. A switching instruction signal, and the signal switching unit connects between the communication unit and the first control unit when the operating system program completes startup. Is a communication method characterized by disconnecting between said second control unit and the communication unit.

Further, the present invention provides a computer of a communication apparatus, a first control unit for controlling a predetermined function unit in the own apparatus based on an operating system program, an external apparatus without being controlled by starting the operating system program And a second control unit for controlling a communication unit that performs predetermined communication , switching between the communication unit and the first control unit, and between the communication unit and the second control unit The first control means outputs a start completion signal when the operating system program completes start-up, and the second control means inputs the start-up completion signal. A first switching instruction signal is output to the signal switching means, and the signal switching means receives the first switching instruction signal and the communication unit With connecting the said first control means, a program characterized by disconnecting between said second control means and the communication unit.

  According to the present invention, it is possible to obtain an effect of shortening the time until the communication function can be used when the communication apparatus is activated.

It is a figure which shows the minimum structure of the communication apparatus by one Embodiment of this invention. It is a figure showing the structure of the communication apparatus 1 by one Embodiment of this invention in detail. It is the figure which showed the flow of the communication data before the starting completion of OS program. It is the figure which showed the flow of the communication data after completion of starting of an OS program. It is a flowchart figure which shows the flow of a process in the control part 111 for voice calls. It is a flowchart figure which shows the flow of a process in CPU101,102. It is a sequence diagram which shows the process and signal flow in each function part.

  Hereinafter, a communication apparatus according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram illustrating a minimum configuration of a communication apparatus according to the embodiment.
In FIG. 1, reference numeral 1 denotes a communication device. The communication device 1 controls a predetermined function unit (including the communication unit 12) in the own device based on at least an OS program (an operating system program). 10 and a second control unit 11 that controls the communication unit 12 that performs predetermined communication with an external device without being controlled by the OS program. The communication device 1 is a communication device that is provided on a command board of a fire fighting radio or a police radio and establishes a voice call with a predetermined mobile station or the like via an emergency / emergency communication network.

FIG. 2 is a diagram showing the configuration of the communication device 1 according to the embodiment in more detail.
2, the communication apparatus 1 includes CPUs 101 and 102, a voice call control unit 111, an encoding / decoding unit 121, a signal processing unit 122, a high-frequency circuit 123, a signal switching unit 13, and relay units 14, 15, and 16. Yes.

Each of the CPUs 101 and 102 is an aspect of the first control unit 10 in FIG. 1, and both are control units that execute predetermined control in the own apparatus based on the OS program. The CPUs 101 and 102 may be general-purpose CPUs used in general computers, but both can be shifted to a state in which processing requested by the user can be executed only after the activation of the OS program is completed. Further, the OS program may be activated by taking several tens of seconds after the communication apparatus 1 is turned on.
In the present embodiment, when the activation of the OS program is completed, the CPUs 101 and 102 output an activation completion signal (Wake signal) for notifying that. Note that the communication apparatus 1 includes two CPUs 101 and 102 and employs a dual CPU system that performs processing in parallel, but the present embodiment is not limited to this mode. The first control unit 10 of the communication device 1 may employ, for example, one CPU (multi-core processor) having a plurality of cores, or may be configured by one CPU having one core.

The voice call control unit 111 is an aspect of the second control unit 11 in FIG. 1, and as a predetermined communication, a communication unit 12 that performs a wireless voice call with an external device (a code / decoding unit 121 described later, signal processing). The control unit 122 controls the high-frequency circuit 123) to realize a wireless voice call function. The voice call control unit 111 can perform the above control without being controlled by the OS program.
When the communication device 1 is turned on, the voice call control unit 111 completes the activation earlier than the activation of the OS program and the execution of the CPUs 101 and 102. That is, the voice call control unit 111 can control the communication unit 12 before the CPUs 101 and 102 can be executed. Therefore, it is assumed that the voice call control unit 111 operates only by reading a dedicated program having a smaller scale than the OS program. The voice call control unit 111 may be configured by hardware such as an analog circuit and a digital circuit that do not require a program. At that time, a programmable logic device such as an FPGA (Field Programmable Gate Array) may be employed so that the user can customize the function of the voice call control unit 111.
Further, the voice call control unit 111 outputs a switching instruction signal (Select signal) for controlling the signal switching unit 13 described later under a predetermined condition.

The encoding / decoding unit 121, the signal processing unit 122, and the high-frequency circuit 123 are functional units that constitute the communication unit 12 in FIG. 1 as an example. The encoding / decoding unit 121, the signal processing unit 122, and the high-frequency circuit 123 are all used for performing a voice call as an example of predetermined communication with an external device.
The encoding / decoding unit 121 is a functional unit that inputs an audio signal emitted from a user via a communication terminal 3 (described later) during audio signal transmission and performs a predetermined encoding process. Also, the encoding / decoding unit 121 performs a decoding process on the wireless audio signal received from the outside via the high-frequency circuit 123 and the signal processing unit 122 when receiving the audio signal.
The signal processing unit 122 is a functional unit that digitally samples an analog waveform received from the outside via the high-frequency circuit 123 when receiving an audio signal, and acquires the audio signal as digital data. The signal processing unit 122 converts the audio signal, which is digital data encoded by the encoding / decoding unit 121 at the time of transmitting the audio signal, into an analog waveform and outputs the analog waveform to the high-frequency circuit 123.
The high-frequency circuit 123 is a functional unit that reshapes a waveform by amplifying or filtering a radio signal sent to an external radio communication network or a radio signal sent from the radio communication network. Specifically, the high frequency circuit 123 includes an analog circuit such as a matching circuit, a filter circuit, and a high frequency amplifier.
Note that the wireless voice call function as described above has been described as an example of the predetermined communication, but the wireless voice call is merely an example, and the present embodiment is not limited to this mode. For example, the predetermined communication may be a wired data communication function using optical fiber technology or the like (not using radio).

The signal switching unit 13 is used to select whether the voice call control unit 111 or the CPUs 101 and 102 perform control of the communication unit 12 (the encoding / decoding unit 121, the signal processing unit 122, and the high frequency circuit 123). This is a signal changeover switch. When the first switching signal (Select 1 signal) is input as the switching instruction signal, the signal switching unit 13 switches the control right of the communication unit 12 from the voice call control unit 111 to the CPU 101 and the CPU 102. Further, when the second switching signal (Select 2 signal) is input, the signal switching unit 13 switches the control right of the communication unit 12 from the CPU 101 and the CPU 102 to the voice call control unit 111. However, in the present embodiment, the signal switching unit 13 may not have a function of switching the control right of the communication unit 12 from the CPU 101 and the CPU 102 to the voice call control unit 111 based on the second switching signal.
Further, the signal switching unit 13 as described above may be configured by a mechanical electrical signal switch, or configured by an analog switch combined with a general-purpose MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). It does not matter.

  The relay units 14, 15, and 16 are for relaying the flow of electrical signals between predetermined functional units. The relay unit 14 connects a control device 2 (described later) that is a host controller of the communication device 1 and the CPUs 101 and 102 of the communication device 1. The relay unit 14 is assumed to be a case where large-capacity data is transmitted / received depending on an application used in the communication apparatus 1, and is preferably, for example, a HUB by Ethernet (registered trademark) having a high data transfer rate. The relay unit 15 connects the communication terminal 3 and the communication device 1 and mainly relays audio signal data. The relay unit 16 connects the voice call control unit 111 and the communication unit 12 (the encoding / decoding unit 121 and the signal processing unit 122), and relays voice signal data in the same manner as the relay unit 15. In the present embodiment, the relay units 15 and 16 are limited in use for transferring small-capacity data such as voice calls. For example, in a HUB or the like using a USB (Universal Serial Bus) with a relatively low data transfer speed. There may be.

  The control device 2 is a host controller that performs various settings and management of the communication device 1 based on user operations. The control device 2 is connected to the CPUs 101 and 102 of the communication device 1 connected via Ethernet (registered trademark) via the relay unit 14. The CPUs 101 and 102 receive command signals from the control device 2, start up various applications that operate on the OS program, and perform various processes such as adjustment of transmission / reception signal levels and frequency allocation settings.

  The communication terminal 3 is an interface device for exchanging communication data including a voice call with a user. If the communication mode is mainly a voice call, the communication terminal 3 may be a voice sensor (microphone) or a receiver connected by USB or the like. Moreover, the communication terminal 3 in this embodiment may transmit / receive large-capacity content data such as an image or a moving image other than a voice call.

FIG. 3 and FIG. 4 are diagrams showing the flow of communication data (voice data) before and after the completion of startup of the OS program.
FIG. 3 shows a state where the activation of the OS program is not completed after the communication device 1 is turned on and the flow of communication data. As shown in FIG. 3, at the stage where the activation of the OS program is not completed, the signal switching unit 13 connects the encoding / decoding unit 121 and the relay unit 16 (via the relay unit 15), and the signal processing unit 122. And the relay unit 16 are connected. In this state, the voice call control unit 111 controls the encoding / decoding unit 121 and the signal processing unit 122 via the relay unit 16.

  In the case of FIG. 3, the flow of communication data during voice transmission will be described below. First, when the communication apparatus 1 receives voice data from a user from the communication terminal 3, the encoding / decoding unit 121 encodes the voice data for wireless communication. Next, the voice call control unit 111 inputs and holds the encoded signal via the relay unit 16 and then outputs the encoded signal to the signal processing unit 122. The signal processing unit 122 performs predetermined modulation on the high-frequency carrier based on the encoded signal that is digital data, converts the high-frequency carrier into an analog signal for wireless communication, and outputs the analog signal to the high-frequency circuit 123. The high frequency circuit 123 transmits the input analog signal to a wireless communication network via a predetermined antenna (not shown).

  Next, the flow of communication data during voice reception will be described below. First, when the communication device 1 receives a wireless signal including audio data from an external device via a wireless communication network and an antenna, the signal processing unit 122 inputs the wireless signal as a predetermined analog signal via the high-frequency circuit 123. To do. The signal processing unit 122 converts the analog signal into a predetermined encoded signal that is a digital signal by performing a digital sampling process or the like. Next, when the voice call control unit 111 acquires the encoded signal via the relay unit 16, the voice call control unit 111 outputs the encoded signal to the encoding / decoding unit 121. The encoding / decoding unit 121 performs a decoding process on the input encoded signal, and decodes the encoded signal into audio data having a predetermined format. The encoding / decoding unit 121 transmits the audio data obtained by decoding to a predetermined communication terminal 3 via the relay unit 15.

  As described above, in a stage before the activation of the OS program is completed, the communication device 1 controls the encoding / decoding unit 121 and the signal processing unit 122 that are the communication unit 12 under the control of the voice call control unit 111. The high-frequency circuit 123 realizes the voice call function. In this case, the voice call control unit 111 may perform predetermined digital signal processing on voice data to be transmitted and received. Further, the voice call control unit 111 may perform only processing for voice data with a light load.

  On the other hand, FIG. 4 shows a state at a stage after the activation of the OS program after the communication apparatus 1 is turned on and the flow of communication data. As shown in FIG. 4, at the stage after the activation of the OS program is completed, the signal switching unit 13 connects the encoding / decoding unit 121 and the CPU 101 (via the relay unit 15), and the signal processing unit 122. And the CPU 102 are connected. At this time, the CPU 101 and the CPU 102 control the encoding / decoding unit 121 and the signal processing unit 122.

  In the case of FIG. 4, the flow of communication data during voice transmission will be described below. First, when the communication apparatus 1 receives voice data from a user from the communication terminal 3, the encoding / decoding unit 121 encodes the voice data for wireless communication. Next, the CPU 101 inputs and holds the encoded signal, and then outputs the encoded signal to the signal processing unit 122 via the relay unit 14 and the CPU 102. The signal processing unit 122 performs predetermined modulation on the high frequency carrier based on the encoded signal that is a digital signal, converts the high frequency carrier into an analog signal for wireless communication, and outputs the analog signal to the high frequency circuit 123. The high frequency circuit 123 transmits the input analog signal to a wireless communication network via a predetermined antenna (not shown).

  Next, the flow of communication data during voice reception will be described below. First, when the communication device 1 receives a wireless signal including audio data from an external device via a wireless communication network and an antenna, the signal processing unit 122 inputs the wireless signal as a predetermined analog signal via the high-frequency circuit 123. To do. The signal processing unit 122 converts the analog signal into a predetermined encoded signal that is a digital signal by performing a digital sampling process or the like. Next, when the CPU 102 acquires the encoded signal, the CPU 102 outputs the encoded signal to the encoding / decoding unit 121 via the relay unit 14 and the CPU 101. The encoding / decoding unit 121 performs a decoding process on the input encoded signal, and decodes the encoded signal into audio data having a predetermined format. The encoding / decoding unit 121 transmits the audio data obtained by decoding to a predetermined communication terminal 3 via the relay unit 15.

  As described above, in the stage after the activation of the OS program is completed, the communication apparatus 1 controls the CPU 101 and the CPU 102 to control the encoding / decoding unit 121, the signal processing unit 122, and the high-frequency circuit that are the communication unit 12. 123 realizes the voice call function. In this case, the CPUs 101 and 102 that operate based on the OS program may perform predetermined digital signal processing on the audio data. In this case, since the functions of the CPUs 101 and 102 are not particularly limited, the CPU 101 and 102 can execute transmission / reception of heavily loaded image and moving image data and digital signal processing of these data.

FIG. 5 is a flowchart showing the flow of processing in the voice call control unit 111.
Next, the flow of processing in the voice call control unit 111 of the communication apparatus 1 will be described step by step with reference to FIG.

  First, when the communication apparatus 1 is turned on by a user operation, the voice call control unit 111 is also turned on (step S51). The voice call control unit 111 starts as soon as the power is turned on, and performs a minimum necessary initialization process (step S52). The initialization processing performed here is completed in a time shorter than the time required for initialization processing (OS program startup processing) in the CPUs 101 and 102 described later.

When the initialization process is completed, the voice call control unit 111 immediately performs the transmission process on the input voice data (step S53). Here, the transmission processing refers to the transmission of audio data (encoded signal) from the encoding / decoding unit 121 to the signal processing unit 122 and the audio data (encoding) from the signal processing unit 122 to the encoding / decoding unit 121. Transmission).
The voice call control unit 111 performs the voice data transmission process in step S53 for a predetermined period (or in parallel with the voice data transmission process), and then receives a start completion signal (wake signal) from the CPUs 101 and 102. It is determined whether or not it has been done (step S54). When the start completion signal has not been input yet, it is determined whether or not there is input of voice data to be transmitted (step S55). If there is voice data to be transmitted, that is, the voice call is continued. If YES in step S53, the flow returns to step S53 to continue transmission processing of necessary audio data.

  On the other hand, when the activation completion signal is input from the CPUs 101 and 102 in step S54, the voice call control unit 111 performs a process of passing the control right of the communication unit 12 to the CPUs 101 and 102. Specifically, a first switching instruction signal (Select1 signal) is output to the signal switching unit 13 (step S56). Here, when the first switching instruction signal is input, the signal switching unit 13 switches the control source of the communication unit 12 from the voice call control unit 111 to the CPU 101 and the CPU 102. Specifically, the signal switching unit 13 disconnects the connection between the encoding / decoding unit 121 and the relay unit 16 (via the relay unit 15), and connects the encoding / decoding unit 121 and the CPU 101. Further, the signal processing unit 122 and the relay unit 16 are disconnected from each other, and the signal processing unit 122 and the CPU 102 are connected (transition from the state of FIG. 3 to the state of FIG. 4). Thereafter, since the ongoing voice call is controlled and executed by the CPUs 101 and 102, the voice call control unit 111 does not receive any voice data in step S56, and the process ends. Note that the voice call control unit 111 may perform a process of transitioning to a sleep state (sleep state) to reduce power consumption when the process ends.

FIG. 6 is a flowchart showing the flow of processing in the CPUs 101 and 102.
Next, the flow of processing in the CPUs 101 and 102 of the communication apparatus 1 will be described step by step with reference to FIG.

  First, when the communication apparatus 1 is turned on by a user operation, the CPU 101 and the CPU 102 are also turned on (step S61). The CPUs 101 and 102 start up as soon as the power is turned on, but as an initialization process, an OS program startup process using a predetermined boot program is performed (step S62). The initialization process (OS program activation process) performed here requires a longer time than the time required for the initialization process in the voice call control unit 111 described above.

  Next, when the OS program completes startup and shifts to a state in which various processes can be executed, the CPUs 101 and 102 output a startup completion signal (Wake signal) (step S63). Here, as described above, the voice call control unit 111 that has received the activation completion signal outputs a first switching instruction signal (Select1 signal) to the signal switching unit 13, and the signal switching unit 13 further When the first switching instruction signal is input, the control source of the communication unit 12 is switched from the voice call control unit 111 to the CPU 101 and the CPU 102. Thereafter, the voice call performed under the control of the voice call control unit 111 is controlled and executed by the CPUs 101 and 102.

  Next, when the switching of the control source is completed, the CPU 101 and the CPU 102 immediately perform transmission processing on the input audio data (step S64). Here, the transmission processing is the same as that performed by the voice call control unit 111, transmission of voice data (encoded signal) from the encoding / decoding unit 121 to the signal processing unit 122, and from the signal processing unit 122. This is transmission of audio data (encoded signal) to the encoding / decoding unit 121. In the case of the CPU 101 and the CPU 102, the function is not limited to a light load transmission process such as audio data, and therefore, for example, it is possible to cope with a large capacity data transmission process such as an image or a moving image. Next, the CPU 101 and the CPU 102 determine whether there is input of voice data to be continuously transmitted (step S65). If there is voice data to be transmitted, that is, if the voice call is continued, Returning to step S64, transmission processing of necessary audio data is continued. When the voice call is finished, the voice data transmission process is finished.

FIG. 7 is a sequence diagram showing the processing and signal flow in each functional unit in time series.
The flow of time-series processing in the voice call control unit 111, the CPUs 101 and 102, and the signal switching unit 13 will be described with reference to FIG.
As shown in FIG. 7, the voice call control unit 111 and the CPUs 101 and 102 perform respective activation / initialization processes at the same time when the communication apparatus 1 is powered on (steps S52 and S62). First, the voice call control unit 111 completes the activation and shifts to voice call processing (voice data transmission processing) (step S53). During this time, the CPUs 101 and 102 are still executing the OS program startup process (step S62). Then, upon completion of the OS program activation process, the CPUs 101 and 102 immediately output an activation completion signal (Wake signal) to the voice call control unit 111 (step S63). When the voice call control unit 111 receives the activation completion signal, the voice call control unit 111 immediately outputs a first switching instruction signal (Select1 signal) to the signal switching unit 13 (step S56). And if the signal switching part 13 which input the 1st switching instruction signal performs a switching process, CPU101,102 will continue a voice call process (step S64).

  As described above, according to the communication device 1 according to the present embodiment, after the power of the device is turned on, the voice call control unit 111 completes the activation quickly, so that the OS program is being activated. Even so, the voice call function can be used. Therefore, it is possible to obtain an effect of shortening the time until the user can use the communication function when the communication device 1 is activated.

  In addition, although the communication apparatus 1 by this embodiment mentioned above demonstrated the aspect which can utilize a communication function during the starting of an own apparatus, in this embodiment, it is not limited to this aspect. For example, communication may be performed during shutdown processing of the communication device 1 based on a user operation or when the processing load on the CPUs 101 and 102 becomes heavy and there is no room for communication processing.

  For example, when the communication apparatus 1 is shut down, the CPUs 101 and 102 output an operation stop signal to the voice call control unit 111 when a shutdown signal for shutting down the own apparatus is input by a user operation. When the operation stop signal is input, the voice call control unit 111 outputs a second switching instruction signal (Select 2 signal) to the signal switching unit 13. Then, when the second switching instruction signal is input, the signal switching unit 13 may switch the control source of the communication unit 12 from the CPU 101 or 102 to the voice call control unit 111. By doing in this way, the communication apparatus 1 by this embodiment can utilize a voice call function also during the shutdown process of an own apparatus.

  Further, when processing by the OS program of the communication device 1 becomes heavy and the CPUs 101 and 102 are in a predetermined overload state, the CPUs 101 and 102 notify the voice call control unit 111 to that effect and receive the notification. The voice call control unit 111 may output a second switching instruction signal to the signal switching unit 13.

DESCRIPTION OF SYMBOLS 1 ... Communication apparatus 10 ... 1st control part 101,102 ... CPU
11 ... Second control unit 111 ... Voice call control unit 12 ... Communication unit 121 ... Encoding / decoding unit 122 ... Signal processing unit 123 ... High frequency circuit 13 ... Signal switching Units 14, 15, 16 ... relay unit 2 ... control device 3 ... communication terminal

Claims (6)

A first control unit that controls a predetermined functional unit in the device based on an operating system program;
A second control unit that controls a communication unit that performs predetermined communication with an external device without being controlled by the program of the operating system;
A signal switching unit that switches connection between the communication unit and the first control unit and between the communication unit and the second control unit;
With
The first control unit outputs a startup completion signal when the operating system program has completed startup,
When the second control unit inputs the activation completion signal, the second control unit outputs a first switching instruction signal to the signal switching unit,
The signal switching unit connects the communication unit and the first control unit and disconnects the communication unit and the second control unit when the first switching instruction signal is input. A communication device characterized by the above. The communication apparatus according to claim 1, wherein the second control unit includes an analog circuit or a digital circuit that does not require a program. The second control unit continues to control the communication unit when there is a signal input from the communication unit even after outputting the first switching instruction signal to the signal switching unit.
The communication device according to claim 1 or 2, wherein When the first control unit inputs a shutdown signal for shutting down its own device by a user operation, it outputs an operation stop signal,
When the second control unit inputs the operation stop signal, the second control unit outputs a second switching instruction signal to the signal switching unit,
The signal switching unit, wherein, when you enter the second switching instruction signal, claims 1, characterized in that switch the control source of the communication unit from the first controller to the second controller 4. The communication device according to any one of 3 . The second control unit controls the communication unit that performs predetermined communication with the external device without being controlled by the operating system program,
The first control unit controls a predetermined functional unit in the own device based on the program of the operating system ,
The signal switching unit switches the connection between the communication unit and the first control unit and between the communication unit and the second control unit,
The first control unit outputs a startup completion signal when the operating system program has completed startup,
When the second control unit inputs the activation completion signal, the second control unit outputs a first switching instruction signal to the signal switching unit,
The signal switching unit connects between the communication unit and the first control unit and disconnects between the communication unit and the second control unit when the operating system program completes startup. A communication method characterized by the above. The communication device computer,
First control means for controlling a predetermined functional unit in the device based on an operating system program;
Second control means for controlling a communication unit that performs predetermined communication with an external device without being controlled by the program of the operating system ;
Signal switching means for switching the connection between the communication unit and the first control unit and between the communication unit and the second control unit
Function as
The first control means outputs an activation completion signal when the operating system program has completed activation,
When the second control means inputs the activation completion signal, the second control means outputs a first switching instruction signal to the signal switching means,
When the first switching instruction signal is input, the signal switching unit connects between the communication unit and the first control unit and between the communication unit and the second control unit. A program characterized by detaching .

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