JPH11234207A - Optical communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable full duplex communication in an infrared ray and radio communication with an easy method and to secure convertibility of a communication device that has only a conventional semi-duplex communication system by performing the full duplex communication when a confirmation means judges that the full duplex communication is possible and otherwise performing the semi-duplex communication. SOLUTION: Communication equipment 110 judges from a communication start request whether or not the communication equipment 100 has a full duplex communication mode. When communication equipment 100 has the full duplex communication mode, the communication equipment 100 transmits a communication start response by adding information to the effect that it has the full duplex communication mode and notifies the communication equipment 100 of it. When the communication equipment 100 does not have the full duplex communication mode, the communication equipment 100 transmits the communication start response without adding the information that the communication equipment 110 has the full duplex communication mode, notifies the communication equipment 100 of it and continues the semi-duplex communication. When the communication equipment 100 has the full duplex communication mode, the full duplex communication is started because it is possible to confirm that the both equipment have the full duplex communication mode.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to optical communication, and particularly to infrared wireless communication.

[0002]

2. Description of the Related Art In infrared wireless communication, communication is performed using a unit having a light emitting unit and a light receiving unit. 2. Description of the Related Art In infrared wireless communication, there is a conventional technique for realizing full-duplex communication by using a method such as frequency multiplexing or time division multiplexing because a communication path is a space and shared.

However, circuits for frequency multiplexing, time division multiplexing, and the like have a high cost due to their complicated structure.

[0004] In infrared wireless communication, a data communication device for transferring data by a half-duplex communication method is now widely used.

[0005]

The full-duplex communication system is superior to the half-duplex communication system as a communication system. However, in order to secure a plurality of communication paths in infrared wireless communication, complicated circuits such as frequency multiplexing and time division multiplexing are required.

[0006] In addition, in order to secure connectivity with devices that are widespread in the world, not only full-duplex communication but also half-duplex communication is required.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical communication system and an optical communication system which enable full-duplex communication in infrared wireless communication by a simple method and which maintain compatibility with a communication device having only a conventional half-duplex communication system. An object of the present invention is to provide a communication method and an optical communication device.

[0008]

A partition plate is provided between a light emitting unit and a light receiving unit, and a communication path is spatially divided by the partition plate. When a plurality of independent communication paths are secured by a switch, non-detection of self-emission, etc., and if a plurality of independent communication paths can be confirmed, negotiation with the other party is performed.
If both are capable of full-duplex communication, the full-duplex communication is performed only when both are possible. Otherwise, half-duplex communication is maintained to maintain compatibility with conventional equipment.

[0009]

FIG. 1 shows the configuration of a device according to the present invention. The communication device 100 is a full-duplex communication processing unit 10
3 and a half-duplex communication processing unit 104, and the communication mode selection unit 102 switches between full-duplex communication and half-duplex communication.

A signal input to the signal input / output terminal 101 passes through one of the full-duplex communication processing unit 103 and the half-duplex communication processing unit 104 selected by the communication mode selection unit 102, and passes through the modulation / demodulation circuit 105. Transmission / reception unit 1 via
06.

A signal received from the transmission / reception unit passes through a modulation / demodulation circuit, passes through a full-duplex communication processing unit or a half-duplex communication processing unit selected by a communication mode selection unit, and receives a signal input / output signal. Output from terminal.

FIG. 2 shows the configuration of the transmitting / receiving unit, that is, the light emitting section and the light receiving section in the present invention. The partition plate 203 of the transmitting and receiving unit 200 is
It is set up to block direct infrared radiation to Similarly, the partition plate 213 in the transmission / reception unit 210 is installed so as to block direct infrared rays from the light emitting unit 211 to the light receiving unit 212.

The partition plates 203 and 213 are adjusted so that when there is a space between the leading ends thereof, the wraparound can be received, and when there is no space, the wraparound cannot be received.

(Embodiment 1) A case in which a communication mode is determined by negotiation while a communication channel is always secured will be described. Communication device 10 in FIG.
In the case of a device in which the communication paths between the communication device 110 and the communication device 110 are independent and plural, that is, in the case of the docking station 300 and the communication device 310 as shown in FIG. Unit layout design so that light emitted from one light emitting unit is not received by the light receiving unit on the same side, light emitted from each light emitting unit does not interfere, and the communication path is independent. Is performed, full-duplex mode negotiation is performed, and full-duplex communication is started.

FIG. 4 shows a time chart in the present embodiment, that is, when the communication mode is determined by negotiation without confirming the securement of the communication path. FIG. 5 shows a flowchart on the communication start side in this case, and FIG. 6 shows a flowchart on the communication response side.

Referring to FIG. 5, when starting communication,
In step S501, the communication device 100
The information that 0 has the full-duplex communication mode is added to the communication start request 401, and the communication start request 401 is sent to the communication device 110 in step S502.

Next, referring to FIG. 6, the communication device 110 extracts information of the communication device 100 from the communication start request 401 received in step S601, and in step S602, the communication device 100 has the full-duplex communication mode. Determine if it is.

If the communication device 100 has the full-duplex communication mode, at step S603 the communication device 110
Is added to the communication start response 402, and the communication start response 402 is transmitted to notify the communication device 100 in step S604.

If the communication device 100 does not have the full-duplex communication mode, the information that the communication device 110 has the full-duplex communication mode is not added, and step S6 is performed.
05, a communication start response 402 is sent out.
0, and the half-duplex communication is continued after step S608. Here, if the communication device 110 does not have the full-duplex communication mode, the communication device 110 cannot extract the information related to the full-duplex communication mode from the communication start request 401 received from the communication device 100. 4
02 does not include information on the full-duplex communication mode.

Next, referring to FIG. 5, the communication device 100 extracts information of the communication device 110 from the communication start response 402 received in step S503, and the communication device 110 has the full-duplex communication mode in step S504. Judge whether it is.

If the communication device 110 has the full-duplex communication mode, it can be confirmed that the communication devices 110 have the full-duplex communication mode. Therefore, the full-duplex communication is started in step S505. If the communication device 110 does not have a full-duplex communication mode, since full-duplex communication is impossible,
The half-duplex communication is continued after step S506.

Referring to FIG. 6, since communication device 110 can determine whether full-duplex communication is possible in step S602, signal 4 from communication device 100 is determined in step S606.
03, and full-duplex communication is started in step S607.

FIG. 7 shows another configuration of the device according to the present invention. The communication device 700 includes a full-duplex communication processing unit 703 and a half-duplex communication processing unit 704, and further includes a switch configuration unit 707 and a switch control 708. The communication mode selection unit 702 switches between full-duplex communication and half-duplex communication. A signal input from the signal input / output terminal 701 is transmitted to the communication mode selection unit 702.
Is transmitted from the transmission / reception unit 706 via the modulation / demodulation circuit 705 via one of the full-duplex communication processing unit 703 and the half-duplex communication processing unit 704 selected. Also,
The signal received from the transmission / reception unit passes through the modulation / demodulation circuit, passes through one of the full-duplex communication processing unit and the half-duplex communication processing unit selected by the communication mode selection unit, and is output from the signal input / output terminal. .

FIG. 8 shows another configuration of the transmitting / receiving unit, that is, the light emitting unit and the light receiving unit in the present invention. The partition plate 803 of the transmission / reception unit 800 is installed so as to block direct infrared rays from the light emitting unit 801 to the light receiving unit 802.

Similarly, the partition plate 813 in the transmission / reception unit 810 is installed so as to block direct infrared rays from the light emitting unit 811 to the light receiving unit 812. This partition plate 80
Reference numerals 3 and 813 denote a transmitting / receiving unit 800 and a transmitting / receiving unit 8
When the distance between the transmission / reception unit 10 and the transmission / reception unit 810 is 0, the wraparound can be received.

The transmission / reception unit 800 includes a switch 804, and the transmission / reception unit 800 and the transmission / reception unit 81.
It is installed so that it turns ON when the 0 partition plate matches. Similarly, a switch 814 is provided in the transmission / reception unit.

(Embodiment 2) A case in which a communication path is confirmed by a switch and a communication mode is determined by negotiation will be described.

Switches of communication devices 800 and 810 are ON.
Is detected, full-duplex mode negotiation is performed, and full-duplex communication is started.

FIG. 9 is a time chart in the present embodiment, that is, a case where the confirmation of the communication path is confirmed by the switch and the communication mode is determined by negotiation. FIG. 10 shows a flowchart on the communication start side in this case, and FIG. 11 shows a flowchart on the communication response side.

Referring to FIG. 10, when starting communication, communication device 800 determines in step S1001 whether the switch is ON. When the switch is ON,
In step S1002, information that the communication device 800 has the full-duplex communication mode is added to the communication start request 901. In step S1003, the communication start request 901 is sent to notify the communication device 810.

When the switch is OFF, the communication device 8
00 without having added the information that it has the full-duplex communication mode, the communication start request 901 in step S1004.
Is sent to the communication device 810, and step S100
Half duplex communication is continued after 8.

Referring now to FIG. 11, communication equipment 810
Is the communication start request 901 received in step S1101.
The information of the communication device 800 is extracted from the
At 2, it is determined whether the communication device 800 has the full-duplex communication mode.

If the communication device 800 has the full-duplex communication mode in step S1102, the process proceeds to step S1102.
At 103, it is determined whether the switch is ON. If the switch is ON in step S1103, step S1103 is executed.
At 1104, information that the communication device 810 has the full-duplex communication mode is added to the communication start response 902, and at step S1105, the communication start response 902 is sent to notify the communication device 800.

In step S1103, the switch is turned off.
In the case of, the information that the communication device 810 has the full-duplex communication mode is not added, and
Sends a communication start response 902 to notify the communication device 800. If the communication device 800 does not have the full-duplex communication mode in step S1102, step S11
At 06, a communication start response 902 is transmitted without adding information that the communication device 810 has the full-duplex communication mode to notify the communication device 810, and the half-duplex communication is continued from step S1109.

If the communication device 810 does not have the full-duplex communication mode, the communication device 810 is set to the communication device 800
Since the information on the full-duplex communication mode cannot be extracted from the communication start request 901 received from the communication start request, the communication start response 902 does not include the information on the full-duplex communication mode.

Next, referring to FIG.
Is the communication start response 902 received in step S1005.
Information of the communication device 810 is extracted from the
At 6, it is determined whether the communication device 810 has the full-duplex communication mode.

If the communication device 810 has the full-duplex communication mode, it is confirmed that the communication devices 810 have the full-duplex communication mode. Therefore, the full-duplex communication is started in step S1007. If the communication device 810 does not have the full-duplex communication mode, since the full-duplex communication is impossible, the half-duplex communication is continued from step S1008.

Referring to FIG. 11, since communication device 810 can determine whether full-duplex communication is possible in step S1103, it receives signal 903 from communication device 800 in step S1107 and full-duplex communication in step S1108. Start heavy communication.

(Embodiment 3) Next, a case will be described in which a communication path is confirmed by a self-luminous reception test and a communication mode is determined by negotiation.

In the communication device 100 and the communication device 110 in FIG. 1, it is assumed that communication is performed from the communication device 100 to the communication device 110.

FIG. 12 shows a time chart in the present embodiment, that is, when the communication path is confirmed by detecting no self-emission and the communication mode is determined by negotiation. FIG. 13 is a flowchart on the communication start side in this case, and FIG. 14 is a flowchart on the communication response side.

Referring to FIG. 13, when starting communication, in step S1301, the communication device 100 adds information that the communication device 100 has the full-duplex communication mode to the communication start request 1201 and then in step S1302. Sends a communication start request 1201 to notify the communication device 110.

Next, referring to FIG.
Is the communication start request 120 received in step S1401.
1, information of the communication device 100 is extracted, and the process proceeds to step S14.
At 02, it is determined whether the communication device 100 has the full-duplex communication mode.

If the communication device 100 has the full-duplex communication mode, the communication device 11
The information that 0 has the full-duplex communication mode is added to the communication start response 1202, and the communication start response 1202 is transmitted in step S 1404 to notify the communication device 100. If the communication device 100 does not have the full-duplex communication mode, the communication device 110 sends a communication start response 1202 in step S1405 without adding information that the communication device 110 has the full-duplex communication mode. Notify the device 100.

If the communication device 110 does not have the full-duplex communication mode, the communication device 110
Since the information about the full-duplex communication mode cannot be extracted from the communication start request 1201 received from the communication start request 1201, the information about the full-duplex communication mode is not included in the communication start response 1202.

Next, referring to FIG.
Is the communication start response 120 received in step S1303.
2, information of the communication device 110 is extracted from step S13.
At 04, it is determined whether or not the communication device 110 has the full-duplex communication mode. If the communication device 110 has the full-duplex communication mode, it can be confirmed that the communication devices 110 have the full-duplex communication mode. In step S1305, a test 1203 is performed to determine whether an independent communication path can be secured. The contents of the test 1203 are the following two points.

The signal of a certain pattern is emitted. -Check whether any signal has been received. Light reception of a pattern other than the emitted signal is not possible because of the large amount of noise and the fact that a secure communication path is not secured. For a signal to emit light, a pattern not included in the test result 1204 to be transmitted later is used.

In order to execute the test 1203, the communication device 110 must not emit light after transmitting the communication start response 1202 until receiving the test result 1204 from the communication device 100. The communication device 100 performs step S130.
In step S1307, the communication device 100 determines in step S1307 that the test result 1204 indicates that full-duplex communication is possible.
Notify 0.

If self-emission is received, step S13
Test result 1 that full-duplex communication is impossible at 08
204 is notified to the communication device 110. Test result 120
For pattern 4, a pattern not used in test 1203 is used.

In step S1307, after transmitting the test result 1204, the communication device 100 does not emit light until it receives the test result 1206 from the communication device 110, as described above. If the communication device 110 does not have the full-duplex communication mode in step S1304, step S13
Half duplex communication is continued after 12.

Next, referring to FIG.
Receives the test result 1204 in step S1406 and the test result 120 received in step S1407.
Judge 4 If the communication device 100 can perform full-duplex communication, the communication device 110 starts a test 1205 in step S1408.

If the communication device 100 is not capable of full-duplex communication, the communication device 110 continues half-duplex communication from step S1413. The content of the test 1205 is the same as the test 1203. The communication device 110 performs step S1
The test result is determined in 409, and if no self-emission is received, the communication device 100 is notified of a test result 1206 that full-duplex communication is possible in step S1410.

If light emission is to be received, step S14 is performed.
Test result 1 that full-duplex communication is impossible at 11
206 is notified to the communication device 100. Test result 120
6 is the same as the test result 1204.

Next, referring to FIG. 13, the communication device 100 receives the test result 1206 in step S1309,
In step S1310, it is determined whether full-duplex communication is possible. If full-duplex communication is possible, step S
After 1311, full-duplex communication starts. If full-duplex communication is not possible, half-duplex communication is continued from step S1312.

Referring to FIG. 14, since communication device 110 can determine whether full-duplex communication is possible in step S1409, it receives signal 1207 from communication device 100 in step S1412 and full-duplex communication in step S1413. Start heavy communication.

[0056]

As a result, when a plurality of independent communication paths can be secured, full-duplex communication is enabled. When the independent communication paths cannot be secured, normal half-duplex communication is performed. Since the currently used half-duplex communication device portion can be used as it is, the circuit configuration is simplified.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a communication device having an infrared transmitting / receiving unit without a switch.

FIG. 2 is a diagram showing an infrared transmitting / receiving unit without a switch.

FIG. 3 is a diagram showing an outline of a docking station.

FIG. 4 is a diagram showing a time chart in a case where a communication mode is determined by negotiation without confirming communication channel securing.

FIG. 5 is a diagram showing a flowchart on the communication start request side in a case where a communication mode is determined by negotiation without confirming communication channel securing.

FIG. 6 is a diagram showing a flowchart on the communication start response side in a case where a communication mode is determined by negotiation without confirming communication channel securing.

FIG. 7 is a diagram showing a configuration of a communication device having an infrared transmitting / receiving unit having a switch.

FIG. 8 is a diagram showing an infrared transmitting / receiving unit having a switch.

FIG. 9 is a diagram illustrating a time chart in a case where confirmation of communication path securing is performed by a switch and a communication mode is determined by negotiation.

FIG. 10: Confirmation of communication path securing is performed by a switch,
FIG. 11 is a diagram illustrating a flowchart on the communication start request side when a communication mode is determined by negotiation.

FIG. 11: Confirmation of communication path securing is performed by a switch,
FIG. 11 is a diagram illustrating a flowchart on the communication start response side when a communication mode is determined by negotiation.

FIG. 12 is a diagram showing a time chart in a case where confirmation of communication path securing is performed by detecting no self-emission and a communication mode is determined by negotiation.

FIG. 13 is a diagram showing a flowchart on the communication start request side in a case where confirmation of communication channel securing is performed by detecting no self-emission and a communication mode is determined by negotiation.

FIG. 14 is a diagram showing a flowchart on the communication start response side in a case where confirmation of communication path securing is performed by detecting no self-emission and a communication mode is determined by negotiation.

[Explanation of symbols]

 Reference Signs List 200 Infrared transmitting / receiving unit 201 Infrared transmitting / receiving unit light emitting unit 202 Infrared transmitting / receiving unit light receiving unit 203 Partition plate between light emitting unit and light receiving unit 210 Infrared transmitting / receiving unit 211 Infrared transmitting / receiving unit light emitting unit 212 Infrared transmitting / receiving unit light receiving unit 213 Between light emitting unit and light receiving unit Partition plate 300 Docking station 310 Communication terminal 800 Infrared transmitting / receiving unit 801 Infrared transmitting / receiving unit light emitting unit 802 Infrared transmitting / receiving unit light receiving unit 803 Partition plate between light emitting unit and light receiving unit 804 Contact detection switch 810 Infrared transmitting / receiving unit 811 Infrared transmitting / receiving unit light emitting unit 812 Infrared Transceiver unit light receiving unit 813 Partition plate between light emitting unit and light receiving unit 814 Contact detection switch

Claims (3)

[Claims] 1. A communication device comprising: confirmation means for confirming whether full-duplex communication is possible with a counterpart device; performing full-duplex communication when the confirmation means determines that full-duplex communication is possible; An optical communication device characterized by performing half-duplex communication in other cases. 2. An optical communication device which performs full-duplex communication only when full-duplex communication is possible with a counterpart device, and otherwise performs half-duplex communication. An optical communication device, comprising: a transmitting / receiving unit including a light-emitting unit and a light-emitting unit, wherein a partition plate is provided between the light-receiving unit and the light-emitting unit. 3. The optical communication device according to claim 2, wherein a contact detection switch is provided at a leading end of the partition plate.