JPH10285117A - Optical transceiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To conduct communication in two-way with a plurality of limited object parties. SOLUTION: A master set 10 placed in a prescribed station and a slave set possessed by each crew are connected through pluralities of optical communication channels 1, 2 to conduct 2-way communication in an outgoing direction from the master set 10 to each slave set 20 and in an incoming direction from each slave set 20 to the master set 10. Moreover, an emergency communication channel 3 in the incoming direction from a prescribed slave set 20 to the master set 10 is provided in addition and used even when the incoming optical communication channel 2 is in use. Furthermore, a voice signal from the optical channel 2 and the emergency communication channel 3 is transferred to each slave set via the optical communication channel 1 with a voice signal from the master set 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transceiver, and more particularly, to an optical transceiver for communicating with a predetermined subject using spatial optical communication.

[0002]

2. Description of the Related Art Conventionally, when calling or communicating with crew members in an aircraft, or calling or communicating with a doctor or nurse in a hospital, callers are required to use broadcasting equipment provided in the aircraft or in the cabin. In this case, the subject is called up to a predetermined place by broadcasting and the message is transmitted, or the message is transmitted directly by broadcasting.

[0003]

However, in such a conventional communication method, a one-way communication from a caller to a target person, in which business communication is performed using broadcast equipment provided in the aircraft or in the hall, is used. Therefore, there is a problem that the subject cannot promptly notify the caller of the presence or absence of the confirmation, and cannot be used as a communication method when urgency or certainty is required. In addition, since the communication method is a broadcast for an unspecified number of people, the details of the communication are also known to other people, so it is not possible to provide specific details as the communication contents. was there. The present invention has been made to solve such a problem, and an object of the present invention is to provide an optical transceiver capable of performing bidirectional communication with a limited plurality of subjects.

[0004]

In order to achieve the above object, an optical transceiver according to the present invention modulates a downstream carrier wave of a predetermined frequency by a sound input from a first microphone during a predetermined operation to transmit a signal. And a first signal having a frequency different from that of the downlink carrier in the received signal.
A base unit that outputs an audio signal obtained by demodulating the upstream carrier wave from the first speaker, and converts a transmission signal from the base unit into an optical signal for transmission and converts a received optical signal to a reception signal. And a plurality of light emitting / receiving units for outputting to the master unit, and an audio signal obtained by demodulating a downlink carrier obtained from the received optical signal from a second speaker, and outputting from a second microphone at a predetermined operation. First by the input voice
And a slave unit for modulating the upstream carrier wave and transmitting the modulated optical signal as an optical signal. Therefore, the downstream carrier is modulated by the voice input at the base unit and transmitted as an optical signal,
This is received by the handset, demodulated, and output as audio. Further, the first uplink carrier is modulated by the voice input by the slave unit and transmitted as an optical signal, which is received by the master unit, demodulated and output as voice.

[0005] Further, the master unit outputs to the speaker an audio signal obtained by demodulating the down carrier and the second up carrier having a frequency different from the first up carrier in the received signal. , One of the first and second uplink carriers is modulated by a sound input from the second microphone at the time of a predetermined operation, and is transmitted as an optical signal. Therefore, the first or second sound is input by the voice input by the slave unit.
Is modulated and transmitted as an optical signal, which is received by the master unit, demodulated, and output as sound.

[0006] Further, the master unit uses a signal obtained by synthesizing a voice signal obtained by demodulating the first and second uplink carriers in the received signal and a voice input from the first microphone, to generate a downlink carrier. Is modulated and output as a transmission signal. Therefore, the voice input by the slave and transmitted by the first and second uplink carriers is synthesized with the voice input by the first microphone, received and demodulated by the master, and transmitted to each slave by the downlink carrier. Is done. Further, when an audio signal is obtained from the second uplink carrier, the master unit is configured to demodulate the audio signal obtained by demodulating the first uplink carrier and the first uplink carrier.
In this case, the downstream carrier is modulated by a voice signal obtained from the second upstream carrier and output as a transmission signal, prior to the voice input from the microphone. Therefore, in preference to the audio signal obtained by demodulating the first uplink carrier and the audio input from the first microphone, the master unit receives and demodulates the audio signal obtained from the second uplink carrier, It is transmitted to each slave unit by a downlink carrier.

[0007] Further, the slave unit outputs a warning display notifying that it is out of the communication area when the downlink carrier obtained from the received optical signal falls below a predetermined reception level. Therefore, when the downlink carrier obtained from the optical signal received by the slave unit falls below a predetermined reception level, a warning display is output to notify the user carrying the slave unit of the outside of the communication area. Is done.

The slave unit is provided with a light emitting / receiving unit for receiving an optical signal from the light emitting / receiving unit and transmitting the optical signal to the light emitting / receiving unit, separately from the main unit of the slave unit. Further, the light emitting / receiving unit of the slave unit is provided in a part of the name tag. Still further, the light emitting / receiving unit of the slave unit is provided on a part of the shoulder boards.
Therefore, the transmission and reception of the optical signal are performed by a light emitting and receiving unit provided separately from, for example, a name tag or an epaulette, separately from the main unit.

A light emitting / receiving unit for receiving an optical signal from the light emitting / receiving unit and transmitting the optical signal to the light emitting / receiving unit is a part of the slave unit, and the slave unit is inserted into a pocket. It is provided on an exposed portion exposed to the outside of the pocket, for example, on an upper side surface or upper surface of the child device. Therefore, an optical signal is emitted from an exposed portion that is a part of the slave unit and that is exposed to the outside of the pocket when the slave unit is inserted into the pocket, for example, a light emitting / receiving unit provided on the upper side surface or the upper surface of the slave. Is transmitted and received.

[0010] The slave unit is provided with a second unit provided in the slave unit body.
, And an earphone or a microphone separate from the second microphone. Therefore, a sound to the slave unit is output by the separate earphone, and a sound from the slave unit is input by the separate microphone. The slave unit is separate from the second speaker and the second microphone provided in the slave unit body, and has an earphone or a microphone connected to the slave unit body via a light emitting / receiving unit. It is. Therefore, sound to the slave unit is output by a separate earphone connected to the slave unit main body via the light emitting / receiving unit, and a separate microphone connected to the slave unit main body via the light emitting / receiving unit. Is input.

[0011]

Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of an optical transceiver according to an embodiment of the present invention. Hereinafter, an example in which the optical transceiver is used as a crew service communication system in an aircraft will be described. In the figure, a base station 10 is a fixed station that is installed at a predetermined packing place inside the plane and communicates with a mobile station owned by each crew member, that is, a slave unit 20, to perform business communication with an arbitrary crew member. is there.

In this case, the master unit 1 is used as an optical communication channel.
0 and each child device 20, a downlink channel 1 for transmitting a signal from the parent device 10 to each child device 20 and an uplink channel 2 for transmitting a signal from the child device 20 to the parent device 10. An upstream channel 3 for transmitting a signal from the slave unit 20 to the master unit 10 in an emergency is provided. Each of the optical communication channels 1 to 3 has a carrier having a different frequency, that is, a downstream carrier, an upstream carrier. (A first uplink carrier) and an emergency uplink carrier (a second uplink carrier).

When a press talk switch (hereinafter referred to as PT) 12 is operated, a microphone (transmitter: first
The downstream carrier wave is modulated by the sound input from the microphone 11), and is transmitted and received as the transmission / reception units 17a to 17n.
Modulating unit 13 for outputting to the light receiving / emitting units 17a to 17
a demodulation unit 14 for demodulating an uplink carrier wave in the received signal from the n. and outputting the obtained audio signal to a speaker (receiver: first speaker) 16;
And an emergency demodulation unit 15 for demodulating the emergency uplink carrier in the received signal from 7n and outputting the obtained audio signal to the speaker 16.

The handset 20 has a demodulation unit 2 for demodulating an upstream carrier wave in a received signal from the light emitting / receiving unit 29 and outputting an obtained audio signal to a speaker (receiver: second speaker) 22.
1, a modulating unit 25 that modulates an upstream carrier with a voice input from a microphone (transmitter: second microphone) 23 when the PT 27 is operated, and outputs the modulated carrier as a transmission signal to the light receiving / emitting unit 29;
Similarly, there is provided an emergency modulator 26 that modulates an emergency uplink carrier with a voice input from the microphone 23 when the PT 27 is operated and outputs the modulated carrier as a transmission signal to the light emitting / receiving unit 29.

Reference numerals 24a and 24b are switches for switching and connecting the output from the microphone 23 and the operation of the PT 27 to either the modulation unit 25 or the emergency modulation unit 26, and are linked together in accordance with a predetermined operation. 22a is the slave 2
A display unit (LED) for notifying a user that the area is outside the reception area when 0 moves outside the reception area.

Light receiving / emitting units 17a to 17 on master device 10 side
n is a plurality of optical antennas arranged on the ceiling or wall inside the device, and a light emitting element that converts a transmission signal output from the modulation unit 13 of the master device 10 into an optical signal (for example, near infrared light) and outputs the signal. And a light receiving element for receiving an optical signal from the light emitting / receiving section 29 of the slave unit 20 and converting the received signal into a received signal.

The light receiving / emitting unit on the side of the handset 20 is provided at a part or an end of the handset 20, or is provided separately from the handset 20 as a crew member's name tag or shoulder board. A light emitting element that converts a transmission signal output from the modulation unit 25 and the emergency modulation unit 26 of the slave unit 20 into an optical signal (for example, near-infrared light) and outputs the converted signal; And a light receiving element for receiving the optical signals from the light emitting units 17a to 17n and converting and outputting the received signals.

Next, the operation of the present invention will be described with reference to FIG. First, when calling any crew member from the base unit 10, the caller operates the microphone 1 while operating the PT12.
Speech input of the crew's name, business, etc. from 1 is performed. As a result, in the modulation section 13, the down carrier is modulated by this audio signal, and each of the light receiving / emitting units 17
a to 17n. Each light receiving / emitting unit 17a-1
In 7n, the light emitting element is driven by this output signal to transmit an optical signal (optical communication channel 1) to the slave unit 20 of each crew member.

The light emitting / receiving section 29 of each slave unit 20 receives the optical signal (optical communication channel 1) by a light receiving element and outputs a received signal. This received signal is transmitted to demodulator 2
1, the downlink carrier in the received signal is demodulated, and the obtained audio signal is output from the speaker 22.
As a result, each crew member listens to the audio output from the speaker 22 to determine whether or not he or she is the call target person, or confirms the contents of the business communication.

If the passenger is the person to be called, the passenger operates the PT 27 to input a voice message from the microphone 23 to the effect that the business contact has been confirmed. This audio signal is normally input to the modulation unit 25 via the switch 24 switched to the modulation unit 25 side, the downstream carrier is modulated by the audio signal, and output to the light receiving / emitting unit 29 as an output signal. . Light emitting / receiving unit 17a-1
In 7n, the light emitting element is driven by this output signal to transmit an optical signal (optical communication channel 2) to the master unit 10 of each crew member.

Light emitting and receiving units 17a to 17 on master device 10 side
n receives the optical signal (optical communication channel 2) by the light receiving element and outputs a received signal. This received signal is input to demodulation section 14 of base unit 10, the downstream carrier in the received signal is demodulated, and the obtained audio signal is output from speaker 16. Thus, the caller of the base unit 10 can
Confirm that the details of the business communication have been notified to the callee.

Note that when the base unit 10 is called from the handset 20 side, the operation is the same as the above-described response communication when the user is the call target. For example, the handset is output from the speaker 22 of the handset 20. When the optical communication channel 2 from the slave unit 20 to the master unit 10 is used by another slave unit 20 based on the contents of the business communication, the communication using the emergency optical communication channel 3 is performed. I do. In this case, first, the switch 24 of the slave unit 20 is switched to the emergency modulation unit 26 side.

As a result, the audio signal from the microphone 23 is input to the emergency modulator 26, where the emergency downlink carrier is modulated by the audio signal and output to the light emitting / receiving unit 29 as an output signal. In the light receiving / emitting units 17a to 17n, the light emitting element is driven by the output signal to transmit an optical signal (optical communication channel 2) to the master unit 10 of each crew member.

Light emitting / receiving units 17a-17 on master device 10 side
n receives the optical signal (optical communication channel 2) by the light receiving element and outputs a received signal. This received signal is input to the emergency demodulation unit 15 of the base unit 10, the down carrier in the received signal is demodulated, and the obtained audio signal is transmitted to the speaker 1.
6 is output. Thus, the master device 10 confirms the business communication from any of the child devices 20.

As described above, the master unit 10 installed at a predetermined packing station and the slave units 20 possessed by each crew are connected via a plurality of optical communication channels, and the master unit 10 descends to each slave unit 20. Since the two-way communication is performed between the direction and the upward direction from any of the slave units 20 to the master unit, the call target person to the caller can be compared with the case where business communication is performed using the conventional broadcasting equipment. Can be promptly contacted for confirmation. In addition, the contents of the contact are not known to an unspecified number of people, and specific contents can be notified as the contact contents. Furthermore, since optical communication is used, it can be used in an environment where the use of wireless communication is restricted, for example, in an airplane or a hospital.

Further, an emergency modulator 26 is provided in the slave unit 20 and an emergency demodulator 15 is provided in the master unit 10, so that modulation and demodulation are performed using emergency uplink carriers different from the uplink carriers. Therefore, even when another slave unit uses the optical communication channel 2 using the upstream carrier,
The master device 10 can be contacted using the optical communication channel 3 using the emergency uplink carrier, and is useful even when urgency or certainty is required.

Further, the audio from the optical communication channel 2 or the emergency optical communication channel 3 may be received by the master unit 10 and transferred to each slave unit via the downstream optical communication channel 1. In this case, the master unit 10 inputs the audio signals obtained from the demodulation unit 14 and the emergency demodulation unit 15 to the modulation unit 13 in the same manner as described above.

Thus, in the same manner as described above, the sound obtained from the demodulator 14 and the emergency demodulator 15 for each slave, that is, the optical communication channel 2 and the emergency optical communication channel 3 from any slave. And the sound from the microphone 11 of the base unit 10 are transmitted to each slave unit, and are transmitted from any slave unit via the optical communication channel 2 and the emergency optical communication channel 3. The received voice call or business communication can be transferred to each slave unit together with the sound from the microphone 11 of the master unit 10, so that not only the notification between the master unit and the slave unit but also between the slave units and the slave unit can be notified. It becomes possible, and the user who has all the slaves can grasp the call contents and the business contact of the other person, and can perform the business smoothly.

In the modulation section 13 of the base unit 10, sound may be simultaneously input from any two or more of the demodulation section 14, the emergency demodulation section 15 and the microphone 11.
In this case, all signals may be combined and transmitted to each slave unit.
5, the downstream carrier is preferentially modulated by the voice signal obtained from the emergency demodulation unit 15 as compared with the voice signal from the microphone 11 and the voice signal obtained from the demodulation unit 14. By doing so, it is possible to prioritize a call or a business contact with high urgency by voice received via the emergency optical communication channel 3 and transfer it to each slave unit.

In the demodulator 21 of the slave unit, when the downlink carrier obtained from the received optical signal falls below a predetermined reception level, it is determined that the mobile station has moved out of the communication area, and it is determined that the mobile station has moved out of the communication area. A warning display for notifying the presence may be visibly displayed on the display unit (LED) 22a. In addition, this type of warning display may be audible by outputting a predetermined warning sound from the speaker 22 or an earphone 22h described below, in addition to the visible display, and may be audible or visible display or audible display. May be displayed. This allows the user to recognize that the user has moved out of the communication area where the optical signal does not reach well and has lost contact, and can take measures such as moving into the communication area. it can.

Next, referring to FIG. 2, the first to fourth embodiments of the present invention will be described.
An embodiment will be described. FIG. 2 is an explanatory diagram showing a configuration example of the light emitting / receiving unit of the slave unit. In FIG. 2A,
The light emitting / receiving unit 29 of the slave unit 20 is provided in a part of the name tag 31 and is connected to the slave unit 20 via wiring. FIG. 2
In (b), the light emitting / receiving unit 29 is provided on a part of the shoulder boards 32,
It is connected to the slave unit 20 via wiring. This allows the light emitting and receiving unit 29 to be disposed on the outer surface of the clothes without a sense of incongruity, and ensures light transmission between the light receiving and light emitting units 17a to 17n of the base unit 10 disposed on the ceiling or wall. Communication can be performed.

FIGS. 2C and 2D show an example in which a light emitting / receiving unit 29 is provided at a part or one end of the slave unit 20. In particular, FIG.
In (c), when the cordless handset 20 is inserted into the breast pocket 33, the light emitting / receiving section 29 is provided on the side exposed outside the breast pocket 33.
Is provided. In FIG. 2D, a light emitting / receiving unit 29 is provided on an upper side surface exposed outside the breast pocket 33 when the child device 20 is inserted into the breast pocket 33. As a result, the light emitting / receiving section 29 can be disposed integrally with the child device 20 on the outer surface of the clothes, and the child device 20 can be inserted into a breast pocket or the like so as to be easily taken out during a call, and can be disposed on a ceiling or a wall. Light receiving / emitting units 17a-1 on the master device 10 side
Optical communication can be reliably performed with the communication device 7n. The same applies to pockets other than breast pockets.

Next, a fifth embodiment of the present invention will be described with reference to FIG. FIG. 3 is an explanatory view showing a foldable (flip-type) slave unit. In this case, the slave 20
Is composed of a main body 20a having a speaker 22, and a flip 20b having a microphone 23 and supported at one end of the main body 20a so as to be openable and closable. Flip 20b
Is closed to the main body 20a when not in use, and is opened from the main body 20a when in use, and the speaker 22 and the microphone 23 are arranged near the ear and the mouth, respectively.

Here, the light emitting / receiving section 29 is a part of the main body 20a, and is provided on the upper side surface exposed outside the breast pocket 33 when the slave unit 20 is inserted into the breast pocket 33. Thereby, even if the child device 20 is a folding type,
The light receiving / emitting unit 29 can be integrally disposed on the outer surface of the clothes, and the optical communication is reliably performed with the light receiving / emitting units 17a to 17n of the base unit 10 provided on the ceiling or the wall. be able to.

The light emitting / receiving section 29 may be provided not on the main body 20a but on the flip 20b. For example, it may be provided on the side of the tip 20 (near the microphone 23) 34 on the flip 20 b side, which is exposed outside the breast pocket 33 when the child device 20 is inserted into the breast pocket 33. Further, a plurality of light emitting / receiving sections 29 shown in FIGS. 2 and 3 may be provided in combination, and the respective effects can be obtained simultaneously.

Next, a sixth embodiment of the present invention will be described with reference to FIG. FIG. 4 is an explanatory diagram showing an example in which an earphone or a microphone is provided separately from the child device on the child device side. Here, an earphone 22h is provided in parallel with the speaker 22 of the slave unit 20. Thereby, the handset 2
Compared to the case where the business communication is heard by the voice output from the speaker 22 of No. 0, the business communication can be surely heard even when the ambient noise is loud, and the contents of the business communication can be heard by a nearby person. Also less.

In FIG. 4, the microphone 23h is
Microphone 23 is provided in parallel. This microphone 2
By attaching the 3h to the chest or the like, there is no need to support the child device 20 at the mouth during voice input, as compared with the case where voice is input using the microphone 23 of the child device 20. When both the earphone 22h and the microphone 23h are provided separately from the slave unit, a headset in which the earphone and the microphone used in a mobile phone or the like are integrated may be used.

When the light emitting / receiving unit 29 is provided separately from the slave unit 20, for example, in the case of a name tag type shown in FIG. 2A or an epaulette type shown in FIG. A connection means such as an earphone jack is provided in the unit 29, and the earphone 2
2h or a microphone 23h may be connected.

[0039]

As described above, according to the present invention, a downstream carrier wave of a predetermined frequency is modulated by a voice input at a master unit and transmitted as an optical signal, which is received by a slave unit, demodulated and output as a voice. At the same time, the first upstream carrier having a frequency different from that of the downstream carrier is modulated by the voice input by the slave and transmitted as an optical signal, which is received and demodulated by the master and output as voice. Compared with the case where business communication is performed using the conventional broadcasting equipment, the callee can promptly notify the caller of the confirmation, which is useful even when urgency or certainty is required. In addition, the contents of the contact are not known to an unspecified number of people, and specific contents can be notified as the contact contents. Furthermore, since optical communication is used, it can be used in an environment where the use of wireless communication is restricted, for example, in an airplane or a hospital.

In the master unit, a second carrier having a frequency different from that of the downlink carrier and the first uplink carrier in the received signal is used.
Demodulates the upstream carrier wave and outputs a voice, and the slave unit modulates either the first or the second uplink carrier wave by the input voice and transmits it as an optical signal. Even when one upstream carrier is used, it is possible to use the second upstream carrier to contact the master unit, which is useful even when urgency or certainty is required. Also,
The master unit modulates a downstream carrier with a signal obtained by combining a voice signal obtained by demodulating the first and second upstream carriers in the received signal with a voice input from the first microphone, and transmits the modulated signal. Since it is output as a signal, it is possible to transfer a call or business communication by voice received from any child device together with the sound from the microphone of the parent device to each child device, and only between the parent device and the child device In addition, the notification between the slave units can be performed, and the user having all the slave units can grasp the contents of the call and the business contact of the other person, and can perform the work smoothly.

Further, in the master unit, when an audio signal is obtained from the second uplink carrier, priority is given to the audio signal obtained by demodulating the first uplink carrier and the audio input from the first microphone. Therefore, the downstream carrier is modulated by the voice signal obtained from the second upstream carrier and output as a transmission signal. Therefore, priority is given to highly urgent calling or business communication by voice arriving via the second carrier. Then, it can be transferred to each slave unit. Further, in the slave unit, when the downlink carrier obtained from the received optical signal becomes lower than the predetermined reception level, a warning display for notifying the outside of the communication area is output, so that the slave unit is carried. The user can recognize that the user has moved out of the communication area where the optical signal does not reach well, and has lost contact, and can take measures such as moving into the communication area.

Further, a light emitting / receiving unit for receiving an optical signal from the light emitting / receiving unit and transmitting the optical signal to the light emitting / receiving unit is provided separately from the main unit. Further, the light emitting / receiving unit of the slave unit is provided in a part of the name tag. Still further, the light emitting / receiving unit of the slave unit is provided on a part of the shoulder boards. Therefore, the light emitting and receiving unit can be arranged on the outer surface of the clothes without a sense of discomfort in fashion, and the optical communication is reliably performed with the light emitting and receiving unit on the master unit disposed on the ceiling, wall, or the like. be able to.

Further, when the light emitting / receiving unit for receiving the optical signal from the light emitting / receiving unit and transmitting the optical signal to the light emitting / receiving unit is a part of the slave unit and the slave unit is inserted into the pocket, It is provided on an exposed portion exposed to the outside of the pocket, for example, on an upper side surface or upper surface of the child device. Therefore, the light emitting and receiving unit can be arranged on the outer surface of the clothes integrally with the slave unit, and the slave unit can be inserted into the breast pocket or the like so that it can be easily removed during a call, and the master unit arranged on the ceiling or wall, etc. Optical communication can be reliably performed with the light receiving / emitting unit on the side.

The slave unit is provided with a second unit provided on the slave unit body.
, And an earphone or a microphone separate from the second microphone. Therefore, a sound to the slave unit is output by a separate earphone or microphone, or a sound from the slave unit is input. The slave unit is separate from the second speaker and the second microphone provided in the slave unit body, and has an earphone or a microphone connected to the slave unit body via a light emitting / receiving unit. It is. Therefore, in the case where a separate earphone is provided, it is possible to reliably hear the business communication even when the ambient noise is loud, as compared to the case where the business communication is heard by the sound output from the speaker of the slave unit. It is unlikely that the contents of the business contact will be asked by a nearby person. Also, by attaching a separate microphone to the chest, etc., there is no need to support the slave unit at the mouth during voice input compared to when using the microphone of the slave unit body to input voice, and excellent workability is obtained. Can be

[Brief description of the drawings]

FIG. 1 is a block diagram of an optical transceiver according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a configuration example of a light emitting / receiving unit of a slave unit.

FIG. 3 is an explanatory diagram showing a foldable child device.

FIG. 4 is an explanatory view showing an example in which an earphone or a microphone is provided separately from the slave unit on the slave unit side.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical communication channel (downlink), 2 ... Optical communication channel (uplink), 3 ... Optical communication channel (emergency uplink), 10 ... Master unit, 11 ... Microphone, 12 ... Press talk switch (P
T), 13: modulation section, 14: demodulation section, 15: emergency demodulation section, 16: speaker, 17a to 17n: light receiving / emitting unit, 20: slave unit, 20a: main body, 20b: flip, 2
1 demodulator, 22, 22h speaker, 23, 23h
Microphone, 24 switch, 25 modulator, 26 emergency modulator, 27 press talk switch (PT), 28
Batteries, 29: light emitting / receiving section, 31: name tag, 32: shoulder boards, 33
... breast pocket, 34 ... tip.

────────────────────────────────────────────────── ─── Continuing on the front page (51) Int.Cl. ⁶ Identification symbol FI H04B 10/26 10/14 10/04 10/06 (72) Inventor Tatsuo Oi 1-112-17, Kamirenjaku, Mitaka City, Tokyo Atsu Inside Den Co., Ltd. (72) Inventor Fukuyuki Kimura 1-112-17, Kamedarijaku, Mitaka City, Tokyo Inside Atsu Den Co., Ltd. (72) Inventor Izio Mochizuki 100 Maeda-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture In company

Claims (12)

[Claims] An optical transceiver for performing communication between a master station as a fixed station and a plurality of slave stations as mobile stations through spatial optical communication, wherein an optical transceiver receives a voice input from a first microphone during a predetermined operation. A downstream carrier of a predetermined frequency is modulated and output as a transmission signal, and an audio signal obtained by demodulating a first upstream carrier of a frequency different from the downstream carrier in the received signal is output from a first speaker. A base unit, a plurality of light receiving / emitting units for converting a transmission signal from the base unit to an optical signal, transmitting the received optical signal, converting the received optical signal to a received signal, and outputting the received signal to the base unit, and the received optical signal. Output from the second speaker, and an audio signal obtained by demodulating the
An optical transceiver, comprising: a handset that modulates a first uplink carrier with a sound input from a second microphone during a predetermined operation and transmits the modulated carrier as an optical signal. 2. The optical transceiver according to claim 1, wherein the master unit demodulates a second upstream carrier having a frequency different from the downstream carrier and the first upstream carrier in the received signal. To a speaker, and the slave unit modulates either the first or the second uplink carrier with a sound input from the second microphone at a predetermined operation and transmits the modulated optical signal as an optical signal. . 3. The optical transceiver according to claim 2, wherein the master unit demodulates the first and second uplink carriers in the received signal and the audio signal input from the first microphone. An optical transceiver, which modulates a downstream carrier with a signal obtained by combining the above and outputs the result as a transmission signal. 4. The optical transceiver according to claim 3, wherein, when an audio signal is obtained from the second uplink carrier, the master unit demodulates the first uplink carrier and the first audio carrier. An optical transceiver, which modulates a downstream carrier with a voice signal obtained from a second upstream carrier and outputs it as a transmission signal, prior to voice input from a microphone. 5. The optical transceiver according to claim 1, wherein the slave notifies the user of out of the communication area when a downlink carrier obtained from the received optical signal becomes lower than a predetermined reception level. An optical transceiver characterized by outputting a display. 6. The optical transceiver according to claim 1, wherein the slave unit includes a light emitting / receiving unit that receives an optical signal from the light emitting / receiving unit and transmits an optical signal to the light emitting / receiving unit. An optical transceiver, which is provided separately from the optical transceiver. 7. The optical transceiver according to claim 6, wherein the light emitting / receiving unit of the slave unit is provided in a part of the name tag. 8. The optical transceiver according to claim 6, wherein the light emitting / receiving unit of the slave unit is provided on a part of the shoulder boards. 9. The optical transceiver according to claim 1, wherein the slave unit includes a light emitting / receiving unit that receives an optical signal from the light emitting / receiving unit and transmits an optical signal to the light emitting / receiving unit. An optical transceiver, wherein the optical transceiver is provided in an exposed part which is a part and is exposed to the outside of the pocket when the slave is inserted into the pocket. 10. The optical transceiver according to claim 9, wherein the exposed portion is an upper side surface or an upper surface of the slave unit. 11. The optical transceiver according to claim 1, wherein the slave unit has an earphone or a microphone separate from the second speaker and the second microphone provided in the slave unit body. Optical transceiver. 12. The optical transceiver according to claim 6, wherein the slave unit is separate from the second speaker and the second microphone provided on the slave unit body, and is connected to the slave unit via a light emitting / receiving unit. An optical transceiver having an earphone or a microphone connected to the main body of the device.