DE19818088B4 - Optical communication unit - Google Patents

Abstract

An optical communication unit (14, 15, 24, 34, 54, 64) provided in a device (2, 3) communicating using optical signals with a second optical communication unit (12, 13, 22, 32, 42 , 52, 62) as a partner, which optical communication unit (14, 15, 24, 34, 54, 64) comprises:
a light emitting section (143, 243, 343, 443, 543, 643) for emitting optical signals;
a driver section for driving the light emitting section;
a control section (141, 241, 341, 441, 541, 641) for changing a driving force of the driving section;
marked by
an engaging portion (14A, 24A, 34A, 34B, 44A, 54A, 64A, 64B) provided on a contact surface with the second optical communication unit (12, 13, 22, 32, 42, 52, 62);
a switching section (147, 247, 344, 447, 547, 644) provided at the engaging portion (14A, 24A, 34A, 34B, 44A, 54A, 64A, 64B) for detecting the connection between the optical communication unit ...

Description

FIELD OF THE INVENTION

The The present invention relates to an optical communication unit and more specifically, an optical communication unit for data communication perform using an infrared beam between a device shaft, such as personal computers or a personal computer and a printer.

BACKGROUND OF THE INVENTION

16 Fig. 10 is a block diagram showing an optical communication unit according to, for example, Japanese Laid-Open Patent Publication No. HEI 8-161089. In the 16 The optical communication unit shown comprises a first communication unit 71 , which is connected to a personal computer and which acts as an optical interface, and includes a second communication unit 81 which is connected to a printer and functions as an optical interface.

This first communication unit 71 and second communication unit 81 have an arbitrary distance between them in accordance with each place where a personal computer and a printer are respectively installed, so that a space according to the space therebetween forms a route for spatial transmission of the infrared ray.

First, the first communication unit comprises 71 a signal conversion circuit 72 for converting electrical signal data output from a personal computer into data for transmission with an infrared ray and an LED driver 73 for driving a light-emitting diode (LED) 74 emitting an infrared ray, an LED 74 emitting an infrared ray, a photodiode (PD) 75 for receiving an infrared beam passing through the LED 84 the second communication unit 81 was emitted, a detector circuit 76 for detecting the infrared ray passing through the PD 75 was received and to obtain data for the infrared ray, and a signal conversion circuit 77 for converting the data of the infrared ray into electrical signal data and for transmitting the electrical signal data to the personal computer.

On the other hand, the second communication unit 81 a signal conversion circuit 82 for converting electrical signal data output from a printer into data for transmission with an infrared ray, an LED driver 83 to drive a LED 84 emitting an infrared ray, an LED 84 emitting an infrared ray, a photodiode 85 for receiving an infrared beam passing through the LED 74 the first communication unit 71 was emitted, a detector circuit 86 for detecting the infrared ray passing through the PD 85 was received and to obtain data for the infrared ray, and a signal conversion circuit 87 for converting the data of the infrared ray into electrical signal data and for transmitting the electrical signal data to the printer.

When next follows a description of the operations of the optical communication unit with the configuration described above.

In the optical communication unit which is in 16 is shown, when data is printed by a printer, an output signal which has been processed by a personal computer by the signal conversion circuit 72 is received and converted into a serial signal for optical communication. When the converted serial signals to the LED driver 73 is sent, the LED driver leaves 73 the LED 74 according to the converted serial signal, flashing and emitting an infrared ray.

The one with the help of the emission through the LED 74 output infrared ray is transmitted through the PD 85 received in the printer. The received infrared beam is further converted as it passes through the detector circuit 86 has been detected, in a signal for controlling the printer in the signal conversion circuit 87 , which is provided in the subsequent stage. The signal for controlling the printer is output to the printer and is processed to control the printer after it is started.

It it should be noted that the Same processing as the one from the personal computer to the printer even with an infrared communication from the printer to the personal computer is performed, but in the reverse order.

However, the conventional type of optical communication unit achieves spatial transmission in the form of a communication mode, so that the optical power is adjusted for a spatial transmission distance of about 1 m. For this reason, when the communication is for a short distance (eg, 0 m), that is, when so-called contact communication is performed, the light on the light receiving side is much stronger than necessary, so that the energy loss on the light emitting side becomes large is. Further, a transmission speed of 4 Mbps is appropriate from the viewpoint of the efficiency of using the light energy for space transmission according to 1 m, however, the transmission speed in the contact communication is too low, even if matching with the optical one Performance is considered.

An optical communication device according to the preamble of claim 1 is known from EP 0 623 891 known. From the US 5,742,602 Network data devices and in particular an adaptive repeater system are known. The EP 0 311 279 describes a semiconductor laser driver system for stabilizing its optical output.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention, an optical communication unit to create a reduction in optical performance and a speed increase a communication speed can be realized, and although with the best balance in between by improving the efficiency the use of energy for the desired optical communication.

These Task is solved by the features of claim 1.

In Advantageously, a driving force for driving a section, which drives a light emitting section in a control section according to one Command changed, which comes from a switching section which changes an optical signal which emits from the light-emitting portion has been. It is possible for this reason the efficiency of using the energy appropriately for the desired improve optical communication.

In Advantageously, an amount of light passing through the light-emitting portion is emitted, as a driving force for the driver section changed, So that the optical power or optical energy by improving the Efficiency of the use of energy appropriately reduced can be, for the desired optical communication.

In Advantageously, a transmission speed an optical signal as a driving force to the driving section changed, so that one Communication speed can be accelerated, and indeed by improving the efficiency of using the energy for the desired optical Communication.

In Advantageously, the switching section provides a command to Switching a driving force to the control section when the connection a device as destination for the transfer has been detected, so that the ordinary executed optical communication is when the connection to the device as a destination for the transfer has not been created and when the connection has been created is, a change takes place in a lot of the light to reduce the optical energy, or a change in a transmission speed, to speed up the communication speed.

at According to the present invention, the switching section provides a command for switching a driving force for the control section, if the connection between a device as the destination for the transfer and an optical cable unit has been detected, so that an ordinary optical communication performed is when the connection between the device as the destination for the transfer and the optical cable unit has not been created and, if the connection has been created, a change takes place in the amount of light to reduce the optical energy, or a change in a transmission speed, to accelerate or increase a communication speed.

In Advantageously, a connection is detected and a change command signal is applied to the control section by a sensor in the switching section issued, so that the Switching section in a safe way, a timing or timing of the switching process receives, and with a simple design.

In Advantageously, the connection is detected and a command to change a driving force to the driver section by a hardware in the Switching section output, so that the switching section in safer Way a timing or timing of the switching process receives, and although with a simple design.

In Advantageously, an optical signal is transmitted through a light receiving section received, so that the Communication does not just consist of a set up communication, by emitting an optical signal but by a duplex communication of infrared rays realized by receiving the optical signals can be.

In Advantageously, the light-receiving section and the light-emitting Section equipped with a same lens, so that accuracy a duplex communication can be ensured insofar as a lot of light and a transmission speed be provided under the same conditions.

at The present invention is a visible light by an optical Cut off filter in the light path to the light-emitting portion as well cut in the light receiving section, so that only an infrared ray with a frequency higher than that of the visible one Light is received or emitted, and it may be for this reason a satisfactory optical communication can be realized.

at The invention concerns the incidence of an optical signal from the light emitting section to the light receiving section by a shielding section within the optical communication unit prevents being in a device for execution a communication is provided, which is an optical signal used, so that a emitted optical signal and a received optical signal do not disturb each other, though the shielding section is provided therebetween and it can for this reason, satisfactory duplex communication will be realized.

In Advantageously, signals are sent to and from a device or received, in the form of a communication partner via a optical cable unit, so that a distance between the device and the device as a communication partner in an arbitrary manner in a state can be adjusted at which a distance or distance to execute optical communications the room is kept constant.

at The present invention is a visible light by means of a optical filter in a light path to the light emitting portion as also prevented or filtered out to the light receiving section, so that satisfactory optical communications can be realized by only an infrared beam is emitted and received, with a frequency that is greater as that of the visible light.

With Help of the invention is provided in a signal transmission / reception section, which is connected to one end of an optical cable, an optical transmission between the device and the optical cable, by the light receiving section and the light emitting Section at the edge portion of the connected optical cable, so that one Communication timing between devices are well maintained regardless of a length of the optical cable.

In Advantageously, a cable has a pair of paths for transmission of optical signals in different directions, So that the Duplex communication within the cable can be realized.

at The present invention provides an optical signal from the light-emitting Section held by a shielding section, so that the signal the light receiving section does not enter, so that an emitted optical Signal and a received optical signal do not influence each other, because of the shielding portion provided therebetween is, and it can therefore be a satisfactory duplex communication will be realized.

In Advantageously, an optical signal is converged by the device and discharged into the optical cable through a first converging lens, and Although in the light receiving portion, and transmitted through the optical cable optical signal is converged and sent to the device with the help of a second condenser lens in the light emitting section, so that only a small number of components in the light receiving / emitting sections is necessary and it may therefore be the whole configuration which realized the transmission and reception of optical signals, simplified and minimized.

With Help of the present invention is an optical signal which through a device has been sent, modulated or demodulated and is incorporated into the optical Cable through a first modulating / demodulating section in the light receiving section sent and an optical signal, which is transmitted via the optical cable has been modulated or demodulated and is being used in the device a second modulating / demodulating section in the light emitting Sent section so that a desired Communication speed according to the specification of a pulse width a transmitted optical signal by the device for modulating and demodulating of the signal can be obtained.

With According to the present invention, the light receiving section and the light-emitting section provided with a same lens, so that one Accuracy of a duplex communication are ensured in this respect can, as a lot of light and a transmission speed be provided under the same conditions.

Advantageously, a circuit for changing an available area thereof according to a communication speed of an optical signal is provided in the light receiving section, so that it is only necessary to use an area which is best suited for communication of the optical signal and it is possible to make the energy consumption more efficient on the basis of this feature become.

In Advantageously, a circuit for changing an available area the same according to a transmission path of an optical signal provided in the light receiving section, so that it it is only necessary to use an area which is most suitable for a transmission link of the optical signal, and with the aid of this feature, the Energy consumption made more efficient.

In Advantageously, a light receiving section and the light emitting Section formed integrally formed with each other and the integrated light receiving / emitter section is with a single piece a converging lens, so that the light receiving / Emittierabschnitt can be minimized and based on this feature the entire unit can be made even smaller.

at The present invention includes the light receiving section and the light-emitting portion is a single convex lens for collecting a optical signal from the device as well as the optical cable, so that only a small number of components in the light receiving / emitting sections is required is and for that reason the whole configuration, which sending out and realizes, simplifies and minimizes the reception of the optical signals can be.

Other Objects and features of the invention will become apparent from the following Description with reference to the attached drawings.

SHORT DESCRIPTION THE DRAWINGS

1 Fig. 12 is a view illustrating a configuration of a system in which an optical communication unit according to Embodiment 1 of the present invention is used;

2 FIG. 12 is a cross-sectional view showing a configuration of the optical communication unit according to Embodiment 1 of the present invention; FIG.

3 Fig. 10 is a block diagram showing the internal configuration of an LSI in a device-side communication unit;

4 Fig. 12 is a view showing an example of a data format used in infrared communication according to Embodiment 1 of the present invention;

5 FIG. 12 is a cross-sectional view showing an internal configuration of an optical communication unit according to Embodiment 2 of the present invention; FIG.

6 FIG. 10 is a cross-sectional view showing an internal configuration of an optical communication unit according to Embodiment 3 of the present invention; FIG.

7 FIG. 10 is a cross-sectional view showing an internal configuration of an optical communication unit according to Embodiment 4 of the present invention; FIG.

8th FIG. 10 is a cross-sectional view illustrating an internal configuration of an optical communication unit according to Embodiment 5 of the present invention; FIG.

9 FIG. 10 is a cross-sectional view showing an internal configuration of an optical communication unit according to Embodiment 6 of the present invention; FIG.

10A and 10B Fig. 11 is views illustrating an example of the arrangement of a light receiving / emitting section in an optical communication unit according to Embodiment 7;

11 Fig. 10 is a circuit diagram showing an example of an LED control circuit according to Embodiment 7;

12 Fig. 10 is a circuit diagram showing an example of a PD control circuit according to Embodiment 7;

13A and 13B Fig. 11 is views illustrating an example of the arrangement of a light receiving / emitting section in an optical communication unit according to a modification 1 of Embodiment 7;

14A and 14B Figs. 10 are views showing an example of the arrangement of a light receiving / emitting section in an optical communication unit according to a variant 2 of Embodiment 7;

15A and 15B Fig. 11 is views illustrating an example of the arrangement of a light receiving / emitting section in an optical communication unit according to a variant 3 of the embodiment 7; and

16 FIG. 12 is a block diagram showing the internal configuration of the optical communication unit based on the conventional technology shows.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

It follows a detailed description of preferred embodiments the optical communication unit according to the present invention having regard to the attached Drawings.

First, a description of the system configuration will be given. 1 FIG. 14 is a view illustrating a configuration of a system in which an optical communication unit according to Embodiment 1 of the present invention is applied. An optical communication unit 1 according to Embodiment 1 comprises a pair of optical fiber cables 11A . 11B each being provided as an optical cable; a pair of cable-side communication units 12 . 13 each serving as a second communication unit for performing infrared communication, and to each of the two ends of the pair of optical fiber cables 11A . 11B are connected; and a pair of device-side communication units 14 . 15 each of which serves as a first communication unit for performing infrared communication and each to each of two ends of the pair of the cable-side communication units 12 . 13 are connected.

The pair of optical fiber cables 11A . 11B transmits optical signals (each obtained by converting an infrared ray into data) in two directions, with one side of the cables serving one direction. In Embodiment 1, one of the optical fiber cables is formed 11A a transmission path for transmitting an optical signal from the cable-side communication unit 13 to the cable side communication unit 12 and the other side of the optical fiber cable 11B forms a transmission path for transmitting an optical signal from the cable-side communication unit 12 to the cable side communication unit 13 ,

The optical communication unit 1 , in the 10 has a system configuration in which the device-side communication units 14 . 15 in a printer 3 as well as in a personal computer 2 are respectively installed, to which the cable-side communication units 12 . 13 each with a cable (optical fiber cable 11A . 11B ) are directly connected. In this system configuration, there is infrared communication between the personal computer 2 and the printer 3 possible.

Each of the cable-side communication units 12 . 13 as well as the device-side communication units 14 . 15 has a light emitting element for emitting an infrared ray IR, and has a light receiving element for receiving an infrared ray IR. Each of the device-side communication units 14 . 15 has a conversion circuit for converting each of a medium between an optical signal and an electrical signal. Each of the device-side communication units 14 . 15 converts a light (infrared ray) from each of the cable-side communication units 12 . 13 is received, in an electrical signal by means of the conversion circuit and outputs the electrical signal to the personal computer 2 or the printer 3 out. Each of the device-side communication units 14 . 15 Also converts an electrical signal from the personal computer 2 is received or from the printer 3 is received, in light (infrared rays), which is done by means of the conversion circuit, and sends the light to each of the respective cable-side communication units 12 . 13 ,

The communications between the device-side communication unit 14 and the cable-side communication unit 12 and the communications between the device-side communication unit 15 and the cable-side communication unit 13 are radio communications with infrared rays. A distance for the signals, over which these are to be transferred spatially via the infrared communication, is a short distance, since both units touch each other. Also, communications between the device-side communication unit 14 and the personal computer 2 as well as between the device-side communication unit 15 and the printer 3 each performed with electrical signals and the communications between the cable-side communication units 12 and 13 over the optical fiber cables 11A and 11B are performed with optical signals.

Next is a description of the internal configuration of each of the communication units. 2 FIG. 12 is a cross-sectional view showing the internal configuration of the optical communication unit according to the embodiment of the present invention. FIG. It should be noted that the cable-side communication units 12 and 13 have the same configuration with each other, so that in the following description for the cable-side communication unit 12 as an example. Similarly, the device-side communication units have 14 and 15 mutually identical configuration, so that the description below in connection with the device-side communication unit 14 serves as an example thereof.

The cable-side communication unit 12 has a frame that has a box shape and it is an optical module 121 to the ends of the optical fiber cables 11A and 11B connected, which is provided within the frame. The optical module 121 owns an LSI 122 for performing infrared communications with the device-side communication unit 14 as well as with the other side of the cable-side communication unit 13 which is provided within the module. Optical filters 12C For cutting off or filtering out a visible light from an optical signal and passing an infrared ray have a frequency higher than that of visible light and they are on a contact surface of the device-side communication unit 14 providing a communication unit as a partner in the frame of the cable-side communication unit 12 is.

On the contact surface are magnets 127 and 128 each adjacent to the optical filters 12C intended. Such magnets 127 . 128 are used to make a magnetic connection to metal sections located at the contact surface of the partner device-side communication unit 14 are provided.

In the optical module 121 are an LED chip 124 as a light-emitting element and a PD chip 126 installed as a light receiving element. More specifically, the optical fiber cable is 11A with the LED chip 124 connected and the optical fiber cable 11B is with the PD chip 126 connected. At positions corresponding to the optical filters 12C in the optical module 121 Opposite are also a large LED lens 123 for the light emission through the LED chip 124 and a PD lens 125 for receiving a light through the PD chip 126 intended.

In a room area in the cable-side communication unit 12 in which the LED lens 123 and the PD lens 125 for the optical module 121 are present, is a shield plate 12b arranged to optically shield a light (infrared rays) from the LED lens 123 is emitted, against a light (infrared rays) passing through the PD lens 125 Will be received. This shielding plate 12B is intended to realize simultaneous optical communications in two directions, namely full duplex communication.

On a portion of the contact surface containing the shielding plate 12B touches is a projecting section 12A in the cable-side communication unit 12 educated. This projecting section 12A consists of a section for engaging or engaging in a concave section 14A located on the contact surface of the device-side communication unit 14 is trained as a partner.

The device-side communication unit 14 has a frame in the form of a box. Within the frame are an LSI 141 which are electrically connected to the CPU of the personal computer 2 connected, and an optical module 142 that electrically with this LSI 141 is connected, provided.

The LSI 141 generates controls for a double speed communication in a state where the communication unit 14 as a partner with the cable-side communication unit 14 connected is. The optical module 142 has an LSI (not shown in the figure) for performing infrared communications with the device-side communication unit 14 as well as with the other side of the cable-side communication unit 13 which is provided within the module.

On the contact surface at the cable side communication unit 14 consisting of a communication unit in the form of a partner in the context of the device-side communication unit 14 There are optical filters 14C each of which filters out visible light of an optical signal and allows only infrared rays to pass at a frequency higher than that of visible light. In the neighborhood of the optical filters 14C are on the contact surface and iron plate parts 145 and 146 each provided with which the magnets 127 and 128 the cable side communication unit 12 as a partner in each case.

In the optical module 142 For example, LED chips are incorporated as a light-emitting element and a PD chip as a light-receiving element, which are not shown in the figure, and an LED lens 143 for the light emission by the LED chip and a PD lens 144 for receiving a light through the PD chip are provided therein, in each case opposite the optical filters 14C ,

In the device-side communication unit 14 provided in the space area in which the LED lens 143 and the PD lens 144 for the optical module 142 are present, is a shield plate 14B available to shield optically light (infrared rays) from the LED lens 143 are emitted from the light (infrared rays) emitted by the PD lens 144 be received. This shielding plate 14B is intended to realize simultaneous two-way optical communication, namely full-duplex communication. In the device-side communication unit 14 is the concave section 14A in which the projecting section 12A the cable side communication unit 12 engages as a partner, provided at a portion of the contact surface, the shielding plate 14B contacted.

Further, a switch circuit for detecting the connection between the engaged units in the engagement portion between the protruding portion 12A and the concave section 14A intended. This switch circuit consists of a double speed mode switch 147 to switch to a double speed mode to perform double speed infrared communication when the cable side communication unit 12 and the device-side communication unit 14 connected to each other. It should be noted that this double speed mode switch 147 if the connection was not detected, switches to an ordinary mode according to infrared communication corresponding to a conventional spatial transmission (1 m).

It should be noted that the double speed mode switch 147 strictly speaking, is used to detect the connection and, for this reason, a switch signal SW obtained by detecting the connection becomes the LSI 141 fed. Accordingly, one unit for the current control of the operations in the double-speed mode or the ordinary mode consists of the LSI 141 ,

In a room between the LSI 141 and the optical module 142 Signal lines are provided for transmitting transmission / reception signals through these lines.

Through the signal lines, a received signal RX from the optical module 142 to the LSI 141 is transmitted and there is a transmission signal TX from the LSI 141 to the optical module 142 Posted.

Next is a description of the configuration of LSI. 3 is a block diagram showing the internal configuration of the LSI 141 in the device - side communication unit, the in 2 is shown, and 4 FIG. 14 is a view illustrating an example of a data format used for infrared communication according to Embodiment 1 of the present invention. FIG. The LSI 141 , in the 3 includes an ISA (Industry Standard Architecture) bus 1000 , an ISA circuit 1001 , an SIR (standard infrared) circuit 1002 , a MIR (Medium Infrared) circuit 1003 , a FIR (first infrared) circuit 1004 , a VFIR (very first infrared) circuit 1005 , a dialing circuit 1006 , an edge detector circuit 1007 , a noise elimination circuit 1008 and a demodulating circuit 1009 ,

The ISA bus 1000 operates at a communication speed of 8 MHz and manages the electronic coupling to the CPU of a personal computer 2 , The ISA circuit 1001 When an infrared ray is transmitted / received, control quantities for a communication speed of the ISA bus are generated 1000 at a usual speed or at a double speed according to a switching signal from the double-speed mode switch 147 (a double speed mode indicates a VFIR mode and a normal speed mode indicates SIR, MIR and FIR modes).

The SIR circuit 1002 consists of a transmission circuit for controlling a pulse width of the transmission data to 3/16 according to a UART (Universal Asynchronous Receiver / Transmitter) mode. For example, infra-red communication may be performed at a baud rate as fast as 115.2 kbps in an IrDA (In Infrared Data Assignment) 1.0 SIR mode. More specifically, this SIR circuit 1002 is used when selecting an ordinary mode and controls a communication speed in the mode ranging from 2.4 kbps to 115.2 kbps.

The MIR circuit 1003 It consists of a transmission circuit for controlling a pulse width of the transmission data to 1/4 according to HDLC (High Level Communication Controller) mode. This MIR circuit 1003 has a function to generate a check bit / check code. This MIR circuit 1003 is used when an ordinary mode is selected and controls a communication speed in the mode up to a range of 0.576 Mbps to 1.152 Mbps. The FIR circuit 1004 has functions for converting the transmission data from 2-bit data into 4-bit data according to a 4 PPM (Four-Valued Pulse Position Modulation) data stream and generates a check bit / check code. This FIR circuit 1004 is used when an ordinary mode is selected and controls a communication speed in the mode up to 4 Mbps.

The VFIR circuit 1005 It has functions for converting the transmission data from 4-bit data to 5-bit data, and generates a check bit / check code. This VFIR circuit is used when the double-speed mode is selected and controls a communication speed in the mode up to 10 Mbps. The dialing circuit 1006 selects the transmission data having a data length from any of the SIR circuit 1002 , MIR circuit 1003 , FIR circuit 1004 or VFIR circuit 1005 according to control variables through the ISA circuit 1001 and it sends the data to the optical module 142 which is provided in the subsequent stage.

The edge detector circuit 1007 is with the optical module 142 and detects an incoming infrared beam from the cable side communication unit 12 was emitted as a partner according to a signal received from the optical module 142 is issued. The noise removing circuit 1008 removes noise (infrared signals generated within a short period of time) from the infrared signal generated by the edge detector circuit 1007 was detected. The modulating circuit 1009 encodes data by expanding a pulse width of the received data opposite to the decoding function by each of the transmitting circuits such as SIR, MIR, FIR and VFIR.

A frame format for the transmission data used for the infrared communication in the ordinary mode and in the double-speed mode includes, as in 4 is shown, a preamble (PA), a start flag (STA), data (DD) and a stop flag (STO).

For example, if the transmission is performed in the ordinary mode at a 4 Mbps transmission rate or transmission rate, then in the FIR circuit 1004 First, a CRC 32 calculation (generation of a check bit / check code) is performed in a frame transmitted from an IrLAP layer, and it becomes CRC 32 added to the end of the IrLAP frame.

Then, coding of the 4 PPM frame is performed, and then a preamble (PA) field and a start flag (STA) field are added to the transmission data to form the header portion thereof. Further, a stop flag (STO) field is added to the end of the frame (after a data (DD) field) and the transmission data is thereby completed. The transmission data used in the FIR circuit 1004 are generated in the manner described above become the optical module 142 via the dialing circuit 1006 sent, which is provided in the subsequent stage, and are sent out at the usual speed.

Even if the transmission is executed in the double-speed mode at a 10 Mbps transmission rate, in the VFIR circuit 1005 first CRC 32 calculated (generating a check bit / check code), namely a calculation in a frame transmitted from IrLAP layer and it becomes CRC 32 added to the end of the IrLAP frame.

Then, the transmission data is converted from the 4-bit data into 5-bit data, and then a preamble (PA) field and a start flag (STA) field are added to the transmission data in order from the header. Further, a stop flag (STO) field is added to the end of the frame (after a data (DD) field) and the transmission data is thereby completed. The in the VFIR circuit 1005 generated transmission data as described above become the optical module 142 via the dialing circuit 1006 transferred, which is provided in the subsequent stage, and are sent out at twice the speed.

In the receive operations is in the LSI 141 an encoding which is opposite to the decoding in the transmission process, carried out, so that the description thereof is omitted here.

Next is a description of the operations of infrared communications between the personal computer 2 and the printer 3 having regard to the 1 and 2 , First, to create an environment for conducting communications, the cable-side communication unit 12 with the device-side communication unit 14 of the personal computer 2 connected and the cable-side communication unit 13 becomes with the device-side communication unit 15 of the printer 3 connected. For making the connection it is easier to position for the attack of the projecting section 12A in the concave section 14A set by the iron plate parts 145 . 146 the device-side communication unit 14 in correlation to the magnet 127 . 128 the cable side communication unit 12 each set for the coupling.

The double speed mode switch 147 for each of the device-side communication units 14 . 15 When a connection between the units has been detected, a switch signal SW for switching from the ordinary mode to the double speed mode transmits to the LSI 141 , In this operation, LSI switches 141 the transmission mode to the double speed mode. Namely, it becomes the 10 Mbps transfer rate with the aid of the VFIR circuit 1005 used by setting the double speed mode.

When print data from the personal computer 2 to the printer 3 are to be sent, an output signal which is in the personal computer 2 was prepared, to the LSI 141 output. In this LSI 141 the transmission data TX (as a frame format which is stored in 4 are shown) are converted into a serial signal for the optical communication and are added to the optical module 142 Posted. The optical module 142 emits an infrared ray from the LED lens 143 according to the transmission data TX transmitted by LSI 141 were received.

It gets visible light from the LED lens 143 emitted light using the optical filter 14C . 12C filtered out for the communication units 14 . 12 , and it becomes for this reason the infrared ray with safety through the PD lens 125 the communication unit (cable-side communication unit 12 ) as a partner. That through the PD lens 125 received infrared light or infrared ray becomes the optical fiber cable 11B through the PD chip 126 in the optical module 121 Posted. In such operations, an infrared optical signal becomes the other side of the cable-side communication unit 13 over the optical fiber cable 11B Posted.

This communication unit 13 for a cable, an operation to start an infrared ray to the device-side communication unit starts 15 (Printer 3 ) as a partner. Namely, it emits the optical module of the cable-side communication unit 13 an infrared ray from the LED lens through the LED chip. Then sets the device-side communication unit 15 the infrared optical signal, when the infrared ray has been received by the PD lens, is converted into an electrical signal in the optical module thereof, and the converted signal is demodulated by the LSI provided in the subsequent stage. Then the printer receives 3 the signal which has been demodulated in the above manner, as a signal for the printer control, and starts the control of the printer.

It should be noted that the same processing as that of the infrared communication from the personal computer 2 to the printer 3 also for infrared communication from the printer 3 to the personal computer 2 is executed in the reverse order. Full duplex communication is used in the embodiment 1, and optical separation can be performed by means of the shield plates 12B and 14B can be achieved and for this reason, simultaneous optical communications in two directions between the printer 3 and the personal computer 2 will be realized.

As has been described above, in the embodiment 1, a pair of cable-side Communication units connected to each other via optical fiber cables and infrared communications between the units where the cable-side communication unit and a device-side communication unit are connected directly to each other, is at a double speed controlled, based on the full-duplex system, so that a distance communication with an optical fiber cable having a length of about 100 m or more possible is, regardless of a length of the optical fiber cable, resulting in high-speed optical communication is made possible and it is also possible a contact communication based on the full-duplex system between to realize the communication units by a specific short distance apart.

Out Because of this, there is no loss of optical energy required for infrared communication is, in the case of a broadcast or transmission based on the Contact communication, so that optical Energy is sufficient, and in an energy size, for the contact communication suitable is. It is therefore possible to reduce the realize optical energy of the LED and a communication speed (e.g., 10 Mbps) with an optimal match therebetween, using the Efficiency of the use of energy is improved and the Energy is made suitable for a desired one optical communication based on the full-duplex system. at This contact communication, which has a sufficient reception capability It is also completely possible to make a speed to realize that is more than twice as big as the highest speed, by the conventional Technology is realized. Because a communication speed of 10 Mbps will connect according to the 10 Mbps Ethernet class possible.

It should be noted that when a switch mechanism with which a user can arbitrarily select an ordinary mode or a double speed mode is discretely provided, unlike the double speed mode switch 147 That is, the ordinary mode can be put into operation even if the connection between the communication units is established, and in this case, a function of power reduction for suppressing the power consumption of the LED in night-time communications can be realized.

It is a shield plate between a light-emitting element and a light receiving element is arranged and thus results no way, the existence infrared ray emitted from the light-emitting element and the infrared ray received by the light receiving element with each other interfere, due to the presence of the shielding plate between. With this feature can realized satisfactory infrared communications based on the full-duplex system become.

There optical communications over optical fiber cables through a pair of cable-side communication units can be self-controlled, a communication timing between the pair of cable-side communication units in a good State, regardless of the length of the optical fiber cable.

There visible light in a light path of an infrared ray from the light-emitting element and by the light-receiving element with an optical filter in the optical module is filtered out, becomes only an infrared ray with a frequency that is higher as that of visible light, received or emitted and because of this satisfactory optical communications are realized.

A device-side Communication unit and a cable-side communication unit are interconnected with a connecting structure and a positional relationship when the device-side communication unit and the cable-side communication unit connected to each other are constant, so that infrared communications at a specified distance at any time for space transmission can be realized.

There the device side Communication unit and the cable-side communication unit can be connected to each other by magneti cal energy, a temporary connection in simple form before meshing carried out and for this reason the operability for a connection can be improved become.

If the device side Communication unit and the cable-side communication unit is not connected to each other becomes the ordinary infrared communication as an ordinary one Infrared communication performed (Air transmission), at the one track for the space transfer within of 1 m, and if, on the other hand, the cable-side communication unit with the device side Communication unit is connected, an infrared communication running under the control of a double speed, and though as contact communication. Because of this, infrared communication can automatically to an ordinary one Speed mode or a dual speed communication mode be switched according to the connection between the device side Communication unit and the cable-side communication unit.

It is also possible to use a hardware switch, such as a dual speed mode switch 147 or to use a whole sensor switch that uses magnetic detection in a switching structure to thereby provide control quantities for a usual speed or for a double speed.

Although the description has been made in connection with the full-duplex infrared communication system in Embodiment 1, similarly to Embodiment 2 described below, the present invention is also applicable to infrared communications based on a half duplex system. It should be noted that the entire configuration thereof is the same as that in Embodiment 1 (see FIG 1 ), so that a description below follows only for different points from the configuration of embodiment 1.

The description deals only with the internal configuration of each of the communication units in the embodiment 2. 5 FIG. 12 is a cross-sectional view illustrating the internal configuration of an optical communication unit according to Embodiment 2 of the present invention. FIG. In the description that follows, an example of a connection between a cable-side communication unit and a device-side communication unit in the personal computer will also be described 2 accepted.

The cable-side communication unit 22 has a frame that is formed as a box and it is an optical module 221 to one of the ends of the optical fiber cable 21A and 21B connected, which is provided within the frame. The optical module 221 owns an LSI 222 for performing infrared communications with a device-side communication unit 24 as well as with the other side of the cable-side communication unit provided inside the module. Optical filters 22B for filtering a visible light of an optical signal and for passing only an infrared ray through the filter have a frequency higher than that of the visible light and they are on the contact surface at the device side communication unit 24 as a partner in the frame of the cable-side communication unit 22 intended.

On the contact surface are magnets 227 and 228 each adjacent to the optical filters 22B intended. Such magnets 227 . 228 are used to be magnetically connected to the metal portions provided on the contact surface, from the device side communication unit 24 that serves as a partner.

In the optical module 221 is an LED chip 224 as a light-emitting element and a PD chip 226 installed as a light receiving element. More specifically, it is an optical fiber cable 21A with the LED chip 224 connected and an optical fiber cable 21B is with the PD chip 226 connected. At positions opposite the optical filters 22B in the optical module 221 are also an LED lens 223 for the light from the LED chip 224 and a PD lens 225 for receiving a light through the PD chip 226 intended.

In the embodiment 2, in the cable side communication unit 22 no shielding plate is provided to optically shield a light (infrared ray) from the LED lens 223 is shielded from a light (infrared ray) shielded by the PD lens 225 Will be received. As described above, the unit does not have a shielding plate provided therein, which enables two-way optical communication to be realized, one for one-way communication, namely, half-duplex communication.

At the same position (contact surface) as the one where the projecting section 12A is provided in the embodiment 1, is a projecting portion 22A provided the same function in the cable-side communication unit 22 Has. The projecting section 22A consists of a section for engaging in a concave section 24A located on the contact surface of the device-side communication unit 24 , which serves as a partner, is trained.

The device-side communication unit 24 has a frame that is formed in a box shape. An LSI 241 is electrical to the CPU of the personal computer 2 connected, and an optical module 242 is electric with this LSI 241 connected, which is provided within the frame. The LSI 241 generates control variables for double-speed communications in a state in which the communication unit 24 with the cable-side communication unit 22 , which serves as a partner, is connected. The optical module 242 has an LSI (not shown in the figure) for performing infrared communications with the device-side communication unit 24 as well as with the other side of the cable-side communication unit provided inside the module.

They are optical filters 24B for filtering a visible light of an optical signal and transmitting only an infrared ray having a frequency higher than that of visible light on the contact surface at the wire-side communication unit 22 provided that forms a communication unit as a partner, in the context of the device-side communication unit 24 , Adjacent to the optical filters 24B are on the contact surface and iron plate parts 245 and 246 provided to the respective magnets 227 and 228 the cable side communication unit 22 , which serves as a partner, are connected.

In the optical module 242 For example, an LED chip as a light-emitting element and a PD chip as a light-receiving element, which are not shown in the figure, are incorporated, and it is an LED lens 243 for the light emission by the LED chip and a PD lens 244 for receiving a light through the PD chip therein, opposite to the respective optical filters 24B ,

In the device-side communication unit 24 No shielding plate is provided to optically transmit a light (infrared ray) from the LED lens 243 is emitted to shield against a light (infrared ray) passing through the PD lens 244 as in the case of the embodiment 1, that is, in a space area in which the LED lens 243 and the PD lens 244 for the optical module 242 available. As described above, no shielding plate is provided therein, which enables realization of optical communications in two directions, each for one-way communication, that is, half-duplex communication. It is in the device-side communication unit 24 the concave section 24A into the protruding section 22A the cable side communication unit 22 , which serves as a partner, engages, provided at a position where the concave section 14A is provided in the embodiment 1.

Further, a switching circuit for detecting the connection between interlocking units in the engaging portion between the protruding portion 22A and the concave section 24A intended. Namely, this switch circuit consists of a double-speed mode switch 247 for switching to a double-speed mode to perform double-speed infrared communication when the cable-side communication unit 22 and the device-side communication unit 24 connected to each other. It should be noted that this double speed mode switch 247 then, if no connection was detected, switched to an ordinary mode for infrared communication, assuming an ordinary space transmission (1 m).

It should be noted that the double speed mode switch 247 strictly speaking, is used to detect the connection and, for this reason, a switch signal SW obtained by detecting the connection becomes the LSI 241 fed. As a result, There is a unit to actually or in actual form control the operations in the double-speed mode or the ordinary mode from the LSI 241 ,

Signal lines for transmitting transmission / reception signals therethrough are in a space between the LSI 241 and the optical module 242 intended. Via the Si gnalleitungen a received signal RX from the optical module 242 to the LSI 241 and a transmission signal TX from the LSI 241 to the optical module 242 transfer. It should be noted that the LSI 241 Control variables for the infrared communications generated in a half-duplex system.

at the optical communication unit according to the embodiment 2 becomes a half-duplex communication executed so that the Need for a shielding plate to optically light rays is separated, and what the configuration even though it will affect the operations in the same Such as those in Embodiment 1, and when communications between the device-side communication unit and the cable-side communication unit are performed in two directions, The infrared communications are based on the half-duplex system executed where a broadcast in one direction and the reception in the other Direction be executed.

As above in connection with the embodiment 2, are a pair of second communication units with each other via optical Fiber cables are connected and there are infrared communications between Units, each with the second communication unit and one first communication unit are connected directly to a double Speed controlled based on the half-duplex system, so that the Contact communication based on the half-duplex system at one specified short distance between the communication units can be realized, regardless of the length of optical fiber cable, resulting in high-speed optical communication allows.

Out For this reason, the optical energy is for performing infrared communication adequate according to an energy required for contact communication is suitable, so that it becomes possible to realize a reduction of the optical energy and the communication speed to increase, and with an optimal balance between these variables, by the efficiency of using the energy for contact communication based is made suitable on the half-duplex system and improved.

Although the description concerned the example of the configuration in which the LED and the PD are separated from each other to perform infrared communication in the half-duplex system of Embodiment 2, similar to Embodiment 3 described below, the present invention is also applicable to the configuration in which an LED and a PD are integrated in the infrared communication in the half-duplex system. It should be noted that the entire configuration thereof is the same as that in Embodiment 1 (see FIG 1 ), so that the following description is made only for the various points other than the configuration of Embodiment 1.

The following is merely a description of the internal configuration of each of the communication units in Embodiment 3. 6 FIG. 12 is a cross-sectional view illustrating the internal configuration of an optical communication unit according to Embodiment 3 of the present invention. FIG. In the following description, an example of the connection between a cable-side communication unit and a device-side communication unit in the personal computer is also an example 2 accepted.

The cable-side communication unit 32 has a frame formed in a box shape and it is an optical module 321 with one end of an optical fiber cable 31 connected, which is provided within the frame. The optical module 321 owns an LSI 322 for carrying out infrared communications with a device-side communication unit 34 as well as with the other side of the cable-side communication unit provided inside the module. An optical filter 32C for filtering a visible light of an optical signal and for transmitting only an infrared ray having a frequency higher than that of the visible light is provided on the contact surface at the device-side communication unit 34 , which represents a communication unit in the form of a partner, in the context of the cable-side communication unit 32 intended.

On the contact surface are magnets 325 and 326 provided, each of which closest to the optical filter 32C is arranged. Such magnets 325 . 326 are used to make a magnetic connection to metal sections located on the contact surface of the device-side communication unit 34 , which serves as a partner, are provided.

In the optical module 321 is a light receiving / emitting chip 324 incorporated by obtaining an LED chip as a light-emitting element and a PD chip as a light-emitting device integrated into the fishing element. An optical fiber cable 31 is with the light receiving / emitting chip 324 connected. Also is a lens 323 for receiving / emitting light at a position opposite to the optical filter 32C in the optical module 321 arranged.

In the embodiment 3, similar to the embodiment 2 in the cable side communication unit 32 no shielding plate is provided to transmit a light (infrared ray) through the light receiving / emitting lens 323 is optically shielded or emitted. As described above, the unit does not have a shielding plate provided therein, which enables realization of two-way optical communications, each of which represents one-way communication, namely half-duplex communication.

In the cable-side communication unit 32 are different to the position where the projecting section 12A is provided in the embodiment 2, projecting portions 32A . 32B at only two places adjacent to the periphery of the light receiving / emitting lens 323. Such protruding sections 32A . 32B are sections in concave sections 34A . 34B in each case on the contact surface of the partner-serving device-side communication unit 34 are provided.

The device-side communication unit 34 has a frame, which is executed in a box shape. An LSI 341 is electrical to the CPU of the personal computer 2 connected and an optical module 342 is electric with this LSI 341 and is provided within the framework. The LSI 341 generates control quantities for double speed communications in a state corresponding to a connection of the communication unit 34 with a partner cable side communication unit 32 , The optical module 342 owns an LSI 347 to infrared communications with the device-side communication unit 34 as well as with the other side of the cable-side communication unit provided inside the module.

An optical filter 34C for filtering out a visible light of an optical signal and transmitting only an infrared ray having a frequency higher than that of the visible light is on the contact surface in the cable-side communication unit 32 provided, which forms a partner forming the communication unit, in the context of the device-side communication unit 34 , Adjacent to the optical filter 34C on the contact surface are also iron plate parts 345 and 346 arranges, with which the magnets 325 and 326 the cable side communication unit 32 which serves as a partner, respectively connected.

In the optical module 342 a light receiving / emitting chip which is not shown in the figure and which is obtained by integrating an LED chip as a light emitting element and a PD chip as a light receiving element is incorporated, and it is also a lens 343 for receiving / emitting light at a position opposite to the optical filter 34C provided therein.

In the device-side communication unit 34 No shielding plate is provided to transmit optical (infrared) light through the receive / emitter lens 343 in contrast to the embodiment 1, in a space area where the receiving / emitting lens 343 for the optical module 342 is available. As described above, no shielding plate is provided therein, which enables realization of optical communications in two directions, each one-way communication, in accordance with half-duplex communication. Here are at the device side communication unit 34 concave sections 34A . 34B for engagement by the projecting portions 32A . 32B each corresponding to a positional relationship between the projecting portions 32A . 32B in the cable-side communication unit 32 which serves as a partner are provided, which positions are different from the position where the concave section 14A is provided in the embodiment 1.

Further, a switch circuit for detecting the connection between interlocking units in one of the intermeshing portions between the protruding portions 32A . 32B and the concave sections 34A . 34B intended. Namely, this switch circuit consists of a double-speed mode switch 344 for switching to a double speed mode to perform double speed infrared communication when the cable side communication unit 32 and the device-side communication unit 34 connected to each other. It should be noted that the double speed mode switch 344 then, if the connection was not detected, switches to the usual mode for infrared communication, assuming a normal space transmission (1 m).

It should be noted that the double speed mode switch 344 in the strict sense is used to detect the connection and for this reason a switch signal SW is obtained by detecting the connection and the LSI 341 fed. As a result, there is one unit to do neuter control of the operations in the double-speed mode or in the ordinary mode from the LSI 341 ,

In a room between the LSI 341 and the optical module 342 Signal lines are provided for transmitting transmit / receive signals therethrough. Via the signal lines, a received signal RX from the optical module 342 to the LSI 341 and a transmission signal TX from the LSI 341 to the optical module 342 transfer. It should be noted that the LSI 341 Control variables for infrared communications generated in a half-duplex system.

The optical communication unit according to Embodiment 3 performs a Half-duplex communication through, so that the need for a shielding Plate to separate optical light beams from each other, eliminated is, as far as the configuration is concerned, it will be However, the operations in the same way as those at the embodiment 1 executed and when communications between the device-side communication unit and the cable-side communication unit are executed in two directions, become infrared communications based on the half-duplex system carried out, where the broadcast in one direction and the reception in the other Direction.

As has been described above, in the embodiment 3, a pair of cable-side Communication units via an optical fiber cable connected together and it will be infrared communications between the units where each cable-side communication unit and device-side Communication unit are connected directly to one another double speed controlled, based on the half-duplex system, and by the use of the optical module, which thereby is achieved by integrating the light receiving / emitting elements so that the Contact communication based on the half-duplex system via a realized short distance between the communication units regardless of length of the optical fiber cable, which is a high-speed optical communication allows and an improvement of the space efficiency as a whole according to the miniaturization of the optical module means.

Out For this reason, the optical energy for carrying out the infrared communication only with an energy value sufficient for the contact communication is suitable, so that it becomes possible reduce the optical power or energy and the communication speed with a best balance in between, increasing the efficiency the utilization of the energy suitably for the contact communication based on the half-duplex system is improved.

Although the light receiving / emitting element is also provided in the cable side communication unit in Embodiment 1, as is the case with Embodiment 4 described below, convergence lenses may be provided instead of the light receiving / emitting elements in the cable side communication unit. It should be noted that the entire configuration thereof is the same as that in Embodiment 1 (see FIG 1 ), so that the following description relates only to the different points, with respect to the configuration of Embodiment 1.

The following is a description of only the internal configuration of each of the communication units in Embodiment 4. 7 FIG. 12 is a cross-sectional view showing the external configuration of an optical communication unit according to Embodiment 4 of the present invention. FIG. In the following description, an example of a connection between a cable-side communication unit and a device-side communication unit in a personal computer will also be described 2 accepted.

A cable-side communication unit 42 has a frame that has a box shape and convergent lenses 421 . 422 , each one on each end of the optical fiber cable 41A . 41B are connected and provided within the frame. They are optical filters 42C each of which serves to filter out visible light of an optical signal and transmit only infrared rays having a frequency higher than that of visible light at the contact surface at a device-side communication unit 44 provided that represents a communication unit as a partner, in the context of the cable-side communication unit 42 intended.

On the contact surface are magnets 423 and 424 arranged, each of which is near the optical filter 42C is located respectively. These magnets 423 . 424 are used to magnetically connect to metal sections located on the contact surface of the partner device-side communication unit 44 are provided.

Each of the convergence lenses 421 . 422 emits a light and receives a light instead of the LED chip 124 and the PD chip 126 in the embodiment 1. In a space area in the cable-side communication unit 42 where the Konver genzlinsen 421 . 422 is a shielding plate 42B provided to optically shield light (infrared light) from the convergence lens 421 emitted to a light (infrared light) passing through the convergence lens 422 Will be received. This shielding plate 42B is intended to simultaneously realize optical communications in two directions, namely full duplex communication.

On a section of the contact surface, the shielding plate 42B is a projecting section 42A in the cable-side communication unit 42 intended. This projecting section 42A consists of a section for engaging in a concave section 44A on the contact surface of the partner-side device-side communication unit 44 is provided.

The device-side communication unit 44 has a frame, which is executed in a box shape. An LSI 441 is electrical to the CPU of the personal computer 2 connected, and an optical module 442 is electric with this LSI 441 connected and arranged within the frame. The LSI 441 generates control variables for double-speed communications in a state according to a connection of the communication unit 44 with the partner cable side communication unit 42 , The optical module 442 has an LSI (not shown in the figure) for infrared communications with the device-side communication unit 44 to realize as well as to realize with the other side of the cable-side communication unit, which is provided within the module.

On the contact surface at the cable side communication unit 42 which serves a communication unit as a partner and in the frame of the device-side communication unit 44 is present, are optical filters 44C each of which cuts or filters out visible light of an optical signal and transmits only infrared light having a frequency higher than that of visible light. Next to the optical filters 44C on the contact surface are also iron plate parts 445 and 446 present to which the magnets 423 and 424 the cable side communication unit 42 , which serves as a partner, each connected or connected.

In the optical module 442 For example, an LED chip as a light-emitting element and a PD chip as a light-receiving element, not shown in the figure, and an LED lens are integrated 443 for emitting a light through the LED chip and a PD lens 444 for receiving a light through the PD chip are provided therein at positions, respectively, in opposition to the optical filters 44C ,

In the device-side communication unit 44 are in a room area where the LED lens 443 and the PD lens 444 for the optical module 442 are present, a shielding plate 44B provided to shield optical light (infrared ray) from the LED lens 443 is emitted from a light (infrared ray) transmitted through the PD lens 444 Will be received. This shielding plate 44B is intended to realize simultaneous optical communications in two directions, namely full-duplex communication. This is the device-side communication unit 44 the concave section 44A into the protruding section 42A the cable side communication unit 42 as a partner, provided at a portion of the contact surface, which the shielding plate 44B touches or hits.

Further, a switch circuit for detecting a connection between interlocking units in the engaging portion between the protruding portion 42A and the concave section 44A intended. Namely, this switch circuit consists of a double-speed mode switch 447 to switch to a double speed mode to perform a double speed infrared communication when the cable side communication unit 42 and the device-side communication unit 44 connected to each other. It should be noted that this double speed mode switch 447 switches to an ordinary mode for infrared communication assuming ordinary space transmission (1 m) when the connection has not been detected.

It should be noted that the double speed mode switch 447 in a strict sense is used to detect the connection and for this reason a switch signal SW is obtained by detecting the connection and the LSI 441 fed. Thus, one unit for actually controlling the operations in the double-speed mode or the ordinary mode consists of the LSI 441 ,

In a room between the LSI 441 and the optical module 442 Signal lines are provided for transmitting transmit / receive signals therethrough. Via the signal lines, a received signal RX from the optical module 442 to the LSI 441 transmitted and a transmission signal TX from the LSI 441 to the optical module 442 transfer.

It should be noted that the operations in the embodiment 4 are the same as those in the embodiment 1, so that a description thereof is omitted. There is ever yet some different points at which optical communications are performed between a pair of cable-side communication units using the convergence lenses 421 . 422 as an optical module in the cable-side communication unit 42 is not provided, and in which a communication speed depends on the partner-serving device-side communication unit.

As above in connection with the embodiment 4, are a pair of cable-side communication units over each other optical fiber cables connected and infrared communications between the units, each of which in the cable-side communication unit has the convergence lenses and the device-side communication unit has the light receiving / Emittierelemente are directly with each other connected and are based on a double speed controlled by the full-duplex system, so that the route communication how the one with an optical fiber cable can be more than 40 m, regardless of length of the optical fiber cable, which is a high-speed optical communication allows and it is also possible the contact communication based on the full-duplex over one specified short distance or distance between the communication units even when realizing the convergence lenses in the cable side Communication unit apply.

Out For this reason, the optical energy is an infrared communication perform, according to an energy value sufficient for contact communication is suitable so that it becomes possible reduce the optical energy and the communication speed to increase, and Although at a best balance between these by the efficiency the use of energy suitably for contact communication is improved based on the full-duplex system. Furthermore other effects are the same as those in the embodiment 1.

Although the light receiving / emitting elements are also provided in the wire-side communication unit in the embodiment 2, similar to the embodiment 5 described below, convergence lenses may be provided in the wire-side communication unit instead of the light-receiving / emitting elements. It should be noted that the entire configuration is the same as that of Embodiment 1 (see FIG 1 ), so that the following description refers only to the different points that are different from the configuration according to the embodiment 1.

The following is a description regarding only the internal configuration of each of the communication units in Embodiment 5. 8th FIG. 12 is a cross-sectional view illustrating the internal configuration of an optical communication unit according to Embodiment 5 of the present invention. FIG. In the following description, an example of a connection between a cable-side communication unit and a device-side communication unit in the personal computer 2 accepted.

A cable-side communication unit 52 has a frame made in a box shape and convergent lenses 521 . 522 are each at each end of the optical fiber cable 51A . 51B connected and provided within the framework. The optical filters 52B each serve to cut off a visible light from an optical signal and to transmit only an infrared ray with a frequency higher than that of visible light, and these filters are on the contact surface at a device-side communication unit 54 is provided, which represents a communication unit in the form of a partner, in the context of the cable-side communication unit 52 intended.

On the contact surface are magnets 523 and 524 each adjacent to the optical filters 52B intended. These magnets 523 . 524 are used so that they are magnetically connected to metal portions on the contact surface of the partner-side device-side communication unit 54 are provided.

Each of the convergence lenses 521 . 522 emits a light and receives a light instead of the LED chip 124 and the PD chip 126 each in the embodiment 1 in the cable-side communication unit 52 is a shielding plate 42B provided to optically shield a light, as shown in the embodiment 4, in a space region where the convergence lenses 521 . 522 available. By means of this feature, it is possible to realize optical communications in two directions, one for one-way communication, namely half-duplex communication.

At the same position (contact surface) as that at which the protruding section 42A is provided in the embodiment 4, is a projecting portion 52A with the same function in the cable side communication unit 52 intended. This projecting section 52A forms a portion for engaging in a concave portion 54A on the contact surface of the partner-side device-side communication unit 54 is trained.

The device-side communication unit 54 has a frame that is formed in a box shape. An LSI 541 is electrical to the CPU of the personal computer 2 connected and an optical module 542 is electric with this LSI 541 connected and this are arranged within the frame. The LSI 541 generates control variables for double-speed communications in a connection state of the communication unit 54 with the partner cable side communication unit 52 , The optical module 542 has an LSI (not shown in the figure) for infrared communications with the device-side communication unit 54 as well as with the other side of the cable-side communication unit provided within the module.

On the contact surface of the cable-side communication unit 52 , which consists of a communication unit as a partner, are in the scope of the device-side communication unit 54 optical filters 54B each of which serves to cut off visible light of an optical signal and to transmit only an infrared ray having a frequency higher than that of the visible light. In the neighborhood of the optical filters 54B are on the contact surface iron plate parts 545 and 546 provided with which magnets 523 and 524 the partner cable side communication unit 52 each connected.

In the optical module 542 Incorporated are an LED chip as a light-emitting element and a PD chip as a light-receiving element, not shown in the figure, and an LED lens 543 for emitting a light through the LED chip and a PD lens 544 for receiving a light through the PD chip are provided therein, in each case in opposition or with respect to the optical filters 54B ,

In the device-side communication unit 54 is not a shielding plate 44B provided to shield a light as in the embodiment 4, that is, in a space area where the LED lens 543 and the PD lens 544 for the optical module 542 available. With this feature, it becomes possible to realize optical communications in two directions, each for one-way communication, namely half-duplex communication. It is in unit-side communication onseinheit 54 the concave section 54A into the protruding section 52A the partner cable side communication unit 52 must intervene, as provided in the embodiment 2.

Further, a switch circuit for detecting the connection between the interlocking units in the engagement portion between the protruding portion 52A and the concave section 54A intended. Namely, this switch circuit consists of a double-speed mode switch 547 to switch to a double speed mode to perform a double speed infrared communication when the cable side communication unit 52 and the device-side communication unit 54 connected to each other. It should be noted that this double speed mode switch 547 switch to an ordinary mode for infrared communication assuming ordinary space transmission (1 m) when no connection was detected.

It should be noted that the double speed mode switch 547 , strictly speaking, is used to detect the connection and, for this reason, a switch signal SW is obtained by detecting the connection leading to the LSI 541 is transmitted. Accordingly, one unit for actually controlling the operations in the double-speed mode or the ordinary mode consists of the LSI 541 ,

In a room between the LSI 541 and the optical module 542 Signal lines are arranged to transmit transmit / receive signals therethrough. Via the signal lines, a received signal RX from the optical module 542 to the LSI 541 transmitted and a transmission signal TX from the LSI 541 to the optical module 542 transfer.

It should be noted that the operations in the embodiment 5 are the same as those in the embodiment 2, so that a description thereof is omitted here. However, there are some different points in which the optical communications differ between a pair of cable-side communication units that are executed using the convergence lenses or converging lenses 521 . 522 because in the cable side communication unit 52 no optical module is provided and according to which a communication speed depends on that of the device-side communication unit used as a partner.

As described above, in Embodiment 5, a pair of wire-side communication units are connected to each other via optical fiber cables, and infrared communications between the units of which convergence lenses are provided in each wire-side communication unit and light-receiving / emitting elements are provided in a device-side communication unit directly involved are connected and controlled at twice the speed based on the half-duplex system, so that it is possible to perform contact communication based on the half-duplex system over a specified short distance between the communication units even if convergence lenses in the cable-side communication unit regardless of the length of the optical fiber cable, which enables high-speed optical communication.

Out For this reason, an optical energy for performing a Infrared communication at an energy level sufficient for a contact communication is suitable, so that it possible is going to reduce the optical energy and a communication speed to accelerate at the best balance in between, by the efficiency of the Use of energy is suitably improved, and though for the contact communication based on the half-duplex system. Furthermore For example, other effects are the same as those of the embodiment Second

Although the description was made for the example of communication in which the LED and the PD are separated from each other to perform infrared communication in the half-duplex system of Embodiment 5, similarly to Embodiment 6 described below Case, the present invention is also applicable to a configuration in which the LED and the PD are integrated for infrared communications based on a half-duplex system. It should be noted that the entire configuration thereof is the same as that in Embodiment 1 (see FIG 1 ), so that a description will be given below only for the deviating points of the configuration according to the embodiment 1.

The following is a description of only the internal configuration of each of the communication units in Embodiment 6. 9 FIG. 12 is a cross-sectional view showing the internal configuration of an optical communication unit according to Embodiment 6 of the present invention. FIG. In the following description, an example of a connection between a cable-side communication unit and a device-side communication unit in the personal computer is also an example 2 accepted.

The cable-side communication unit 62 has a frame that has a box shape, and it is a convergent lens 621 connected to one end of an optical fiber cable 61 is provided within the framework. The convergence lens 621 is done by integrating the convergence lenses 521 . 522 in Embodiment 5, it receives and emits light as well as receives light by means of this single lens. An optical filter 62C for cutting off or filtering out a visible light of an optical signal and for transmitting only an infrared ray having a frequency higher than that of visible light is on the contact surface at a device-side communication unit 64 provided as a communication unit in the form of a partner in the context of the cable-side communication unit 62 is available.

On the contact surface are magnets 622 and 623 provided, each in close proximity to the optical filter 62C are arranged. These magnets 622 . 623 are used to be magnetically connected to metal portions located on the contact surface of the partner device-side communication unit 64 are provided.

Here are the cable-side communication unit 62 different from the position where the projecting section 52A is provided in the embodiment 5, projecting portions 62A . 62B at only two locations adjacent the circumference of the convergence lens 621 intended. These protruding sections 62A . 62B consist of sections for engaging in concave sections 64A . 64B , each on the contact surface of the serving as a partner device-side communication unit 64 are provided.

The device-side communication unit 64 has a frame made in a box shape. Within the frame are an LSI 641 which are electrically connected to the CPU of the personal computer 2 connected, and an optical module 642 that electrically with this LSI 641 is connected, provided. The LSI 641 generates control quantities for double-speed communications in a state of connection of the communication unit 64 with the partner cable side communication unit 62 , The optical module 642 has an LSI (not shown in the figure) for infrared communications with the device-side communication unit 64 as well as with the other side of the cable-side communication unit provided inside the module.

On the contact surface at the cable side communication unit 62 consisting of a partnering communication unit is in the frame of the device-side communication unit 64 an optical filter 64C is provided to cut off or filter out a visible light from an optical signal and to pass only an infrared beam therethrough, which has a frequency which is higher than that of the visible light. Adjacent to the optical filter 64C are on the contact surface iron plate parts 645 and 646 provided to the magnets 622 and 623 the cable side communication unit 62 , which serves as a partner, each connected or connected.

In the optical module 642 That is, a light receiving / emitting chip which is obtained by integrating an LED chip as a light emitting element and a PD chip as a light receiving element, not shown in the figure, is a light receiving / emitting lens 643 for receiving / emitting a light therein at a position opposite to the optical filter 64C intended.

In the device-side communication unit 64 No shielding plate is disposed in a space area where the light-receiving / emitting lens 643 for the optical module 642 is available. As described above, no shielding plate is provided, which enables two-way optical communication to be realized, one for one-way communication, namely, half-duplex communication. Here are at the device side communication unit 64 the concave sections 64A . 64B into which the projecting sections 62A . 62B engage respectively, according to a positi ons relationship between the projecting portions 62A . 62B in the cable-side communication unit 62 , which serves as a partner, are provided.

Further, a switch circuit for detecting a connection between the interlocking units at one of the intermeshing portions between the protruding portions 62A . 62B and the concave sections 64A . 64B intended. Namely, this switch circuit consists of a double-speed mode switch 644 to switch to a double speed mode to perform double speed infrared communication when the cable side communication unit 62 and the device-side communication unit 64 connected to each other. It should be noted that this double speed mode switch 644 in an ordinary mode for infrared communication assuming ordinary space transmission (1 m) when no connection is detected.

It should be noted that the double speed mode switch 644 strictly speaking, is used to detect the connection and for that reason a switch signal SW is obtained by detecting the connection and this becomes the LSI 641 fed. Thus, one unit for actually controlling the operations in the double-speed mode or the ordinary mode consists of the LSI 641 ,

In a room between the LSI 641 and the optical module 642 signal lines are provided to transmit transmit / receive signals therethrough. Via the signal lines, a received signal RX from the optical module 642 to the LSI 641 and a transmission signal TX from the LSI 641 to the optical module 642 transfer. It should be noted that the LSI 641 Control variables for infrared communications generated in the half-duplex system.

The optical communication unit according to Embodiment 6 performs a Half-duplex communication through, so that the need for a shielding Plate to optically separate or shield light rays from each other, is eliminated, and as far as the configuration is concerned, it will however, the operations in the same way as those at the embodiment 4 executed and when communications between the device-side communication unit and the cable-side communication unit are executed in two directions, so will the infrared communications based on the half-duplex system performed at sending in one direction and receiving in the other Direction performed become.

As has been described above, in the embodiment 6, a pair of cable-side Communication units with each other via an optical fiber cable connected and the infrared communications between the units, each of the cable-side communication units is a convergence lens contains and every device side Communication unit contains an optical module are obtained by by directly connecting light receiving / emitting elements be and according to one Double speed controlled based on the half-duplex system be so that it possible is a contact communication based on the half duplex system via a specified short distance between the communication units even then perform if a convergence lens in the cable-side communication unit regardless of length of the optical fiber cable, which is a high-speed optical communication allows and where the spatial Efficiency as a whole according to the minimization of the optical module is improved.

For this reason, an optical energy for performing the infrared communication is sufficient if only an energy value is used, which is suitable for a contact communication, so that it is possible to reduce the opti realizing energy and realizing an acceleration of a communication speed with the best balance between sizes by improving the efficiency of using the energy suitable for the contact communication and based on the half-duplex system. In addition, other effects are the same as those in the embodiment 3.

The embodiment 7 of the present invention, which will be described below shows a special case of the arrangement of LEDs and PDs in the integrated configuration of the LEDs and PDs according to the embodiment 3. According to this embodiment 7, an optical communication unit using the Configuration according to the embodiment 3, which has been described above, so that the representation as well a description thereof are omitted here. It follows here a description of merely characteristic sections of these embodiment 7th

First, a description will be given regarding an arrangement of the LEDs and the PDs corresponding to the light receiving / emitting section. The following is a description of the light receiving / emitting section of a device-side communication unit 34 given. The 10A and 10B FIG. 15 is views showing an example of arrangement of a light receiving / emitting section in an optical communication unit according to Embodiment 7 of the present invention, and FIGS 10A and 10B FIG. 15 is a side cross-sectional view and a front view each showing the light receiving / emitting section. The light receiving / emitting section in the device side communication unit 34 comprises an optical module 342 and a light receiving / emitting lens 343 , In the optical module 342 are, like this in 10A is shown, a light receiving section (PD 348A for FIR, PD 349A for SIR) and a light emitting section (LED 350A for a long distance, LED 351A for a short distance), and the light-emitting portion and the light-receiving portion are connected to the light-receiving / emitting lens 343 covered, which has a curved shape.

The arrangement of the light receiving / emitting section is in 10B shown. It is the LED that forms 350A for a long distance and LED 351A each for a short distance, the light emitting portion and are side by side in the vertical direction at a center of the light emitting / receiving lens 343 positioned. Also make PD 348A for FIR and PD 349A for SIR each have a light receiving section and are positioned so that the light emitting section located at a center of the light emitting / receiving lens 343 is located, is held in between.

The LED 350A for a long distance or distance and the LED 351A for a short distance or distance are used case by case according to a communication link or a communication mode. In other words, if a communication distance is long (eg 1 m) or in case of a space transmission mode both LEDs are used and if the communication distance or distance is short (eg 50 cm), only the LED becomes 351A used for a short distance. Also be PD 348A for FIR and PD 349A used for SIR on a case-by-case basis according to a communication speed. For example, when light is received at a communication speed of up to 4 Mbps, PD becomes 348A for FIR and PD 349A is used for SIR, and when light is received at a communication speed of up to 115 kbps, only becomes PD 349A used for SIR.

Next is a description of the circuit configuration around the LED. 11 FIG. 12 is a circuit diagram illustrating an example of an LED control circuit according to Embodiment 7. FIG. This LED control circuit is connected to a power supply control terminal 2001 and a transmission signal terminal 2006 the LSI 347 , which has been described above. A signal for controlling a required power supply or power becomes the power control terminal 2001 according to the long transmission path or the short transmission path as described above. For example, if SW indicates a communication mode according to an extremely short transmission distance, or if only the LED 351A is used for a short distance in a case where a CPU issues a command for power saving, the LSI speaks 347 to the command from SW or the CPU, and a power control signal of "0" becomes the power control terminal 2001 fed. If, on the other hand, both the LED 350A for a long transmission distance and the LED 351A for a short link, as in a case where SW indicates a space transmission or where the CPU issues a command to increase a light emission rate, the LSI speaks 347 to a command from SW or the CPU, and a power control signal of "1" becomes the power control terminal 2001 fed. Also, a transmission signal (1/0) for the light emission by the LED becomes the transmission signal terminal 2006 fed. It should be noted that when SW and CPU respectively output different signals, the LSI 347 works such that a command is preferably processed by the CPU.

The LED 350A for a long transfer track is about a resistance 2005 is connected to a power supply unit (not shown) on the upstream side and is connected to a collector of a transistor 2004 connected in the downstream side. In this transistor 2004 the emitter is grounded (GND) while the base is connected to an output terminal of an AND gate 2003 connected is. An amplifier 2002 for a signal amplification and a transmission signal terminal 2006 that ever with the power control terminal 2001 are connected to an input terminal of the AND gate 2003 connected. The AND gate 2003 provides control quantities via an ON / OFF output to the base terminal according to a logical product between the input from the transmission signal terminal 2006 and the input from the power control terminal 2001 ,

Also is the LED 351 A for a short distance over a resistor 2008 is connected to a power supply unit (not shown) on the upstream side and is connected to a collector of a transistor 2009 connected on the downstream side. In this transistor 2009 the emitter is grounded (GND) while the base of it is connected to an amplifier 2007 for signal amplification connected to the transmission signal terminal 2006 connected is.

In the above-described LED control circuit, when a power control signal of "1" is given to the power control terminal 2001 is inputted, an ON / OFF signal becomes a base terminal of the AND gate 2003 fed, namely a base terminal of the transistor 2004 according to a change to 1 or 0 of the transmission control signal which is the transmission signal terminal 2006 is fed. Namely, when the ON signal is input, a current flows between a collector and an emitter of the transistor 2004 at the LED 350 for a long transmission path that is turned ON (emits light) and, when the OFF signal is input, becomes a current that flows between a collector and an emitter of the transistor 2004 flows, cut off, with the LED 350A is switched OFF for long distance transmission.

At the same time will also be a transistor 2009 ON or OFF according to the change of a transmission signal to 1 or 0. Namely, when the transmission signal is ON, a current flows between a collector and an emitter of the transistor 2009 , where the LED 351A is turned ON for a short transmission path and when the transmission signal is OFF, the current flowing between a collector and an emitter of the transistor 2009 flows, interrupted, with the LED 351A is switched OFF for a short transmission distance. With this feature, the light emission with increased energy from both the LED 350A for a long transmission distance as well as the LED 351A controlled for a short transmission distance for transmission over a long distance or distance.

On the other hand, if the power control signal of "0" is the power control terminal 2001 is fed, no signal from the AND gate 2003 a base terminal of the transistor 2004 fed during the period during which the LED 350A is switched to the OFF state for a long transmission path and it is only the LED 351A for a short transmission line ON or OFF, according to a transmission signal. With this feature, a light emission with suppressed energy from only the LED 351A controlled for a short distance for transmission over a short distance.

Next is a description of a circuit configuration around the PD. 12 FIG. 12 is a circuit diagram illustrating an example of a PD control circuit according to Embodiment 7. FIG. This PD control circuit is provided with a speed control terminal 3012 and a reception signal terminal 3011 the LSI 347 connected, which has been described above. A switching signal for controlling a reception speed to that suitable for SIR or FIR described above becomes the speed control terminal 3012 fed. For example, if only the PD 349A is used for SIR, the signal of "0" becomes the speed control terminal 3012 fed and if both PD 349A for SIR and PD 348A for FIR, the signal of "1" becomes the speed control terminal 3012 fed.

The PD 348A for FIR is with a switch 3014 connected. This switch 3014 generates a switching operation to generate a signal which is generated by PD 349A for SIR, to be superimposed to that which is PD 348A received for FIR. When a switching signal (amplified by an amplifier 3013 ) from the speed control terminal 3012 is fed from equal to "1", this switch is 3014 ON and there will be a signal coming through PD 348A for FIR, superimposed on the one from PD 349A received for SIR.

Between PD 349A for SIR and a receive signal port 3011 For example, three stages of a signal amplifying block are provided. In the direction of PD 349A for SIR to the receive signal terminal 3011 For example, the first stage of the signal amplifying block includes a gain feedback resistor 3001 , an amplifier 3002 , a capacitor 3003 (GND); the second stage of the signal amplifying block includes a gain feedback resistor 3004 , an amplifier 3006 and a capacitor 3005 (GND); and the third stage of the signal amplifying block comprises an amplifier 3007 and a capacitor 3008 (GND). A comparator 3009 and a resistance 3010 are connected to a rear portion of this third stage of the signal amplifying block, so that only a reception signal of a level specified in advance to the reception signal terminal 3011 is issued.

When in the PD control circuit described above, a switching signal of "0" is applied to the speed control terminal 3012 is entered, the switch becomes 3014 held in the OFF state, where PD 348A for SIR does not carry out a signal overlay via a signal which is transmitted by PD 349A was received for FIR and it becomes only PD 349A used for SIR to receive a signal. In this case, only a signal transmitted by PD 349A for SIR is amplified over the three stages of the signal-enhancing block. When this amplified signal is at the predetermined level or at a higher level in the comparator 3009 is the signal as a correctly received signal from the received signal terminal 3011 to the LSI 347 output.

When the switch signal of "1" is the speed control terminal 3012 is entered, the switch becomes 3014 ON, whereby one by PD 349A for FIR received signal is superimposed on that which by PD 348A received for SIR. This superimposed signal is amplified by three stages of the signal-amplifying block on the downstream side. When this amplified signal is at a predetermined level or at a higher level within the comparator 3009 is the signal as a correctly received signal from the received signal terminal 3011 to the LSI 347 output.

It should be noted that a power control signal supplied by the LSI 347 is supplied to the LED control circuit, and a switching signal supplied to the PD control circuit is decided by means of a connection to a partner device or by the communication protocol. Accordingly, when a transmission is decided over a long transmission route, the power control signal is input as "1", and when the transmission is decided over a short transmission route, the power control signal is input as "0". When the use of SIR is decided, the switching signal is input as "0", and when the use of FIR is decided, the switching signal is input as "1".

As has been described above, in this embodiment, 7 of the present Invention of the light receiving / emitting section minimized to a required minimum size and at the same time with one piece a convergence lens occupies (light receiving / emitter lens), so that one further size reduction can be realized, compared with those at the other Embodiments is possible. By further including a surface the light receiving / emitting lens with a loose inclination angle in a range of 30 degrees to 60 degrees, thereby forming a Adaptation to the room transmission perform, For example, communication can be carried out at a wide angle and a limitation concerning the positional relationship at a light receiving / emitting section a partner can be neglected become.

at the light receiving section (on the PD side) may have an available area the same according to one Communication speed of an optical signal to be changed so that only one Area that is extremely for a communication speed the optical signal is suitable, can be used and on the other hand is a circuit in the light emitting portion (on the side of the LED) provided a change a used range according to a transmission distance of an optical signal, so that only one area, the is optimally suited for a transmission path an optical signal can be used. With this feature Energy consumption can be made more efficient.

The exemplary arrangement of the LEDs and the PDs in the embodiment 7, described above, is only one Example and the next Description concerns representative Modifications thereof.

The 13A and 13B FIG. 12 is views showing an example of arrangement of a light receiving / emitting section in an optical communication unit according to a modification 1 of the embodiment 7 described above, and FIGS 13A and the 13B FIG. 12 shows a side cross-sectional view and a front view, each of which depicts the light receiving / emitting section, respectively. In this variant 1, the light receiving / emitting section includes in the device side communication unit 34 an optical module 342 and a light receiving / emitting lens 343 , as in 6 is shown. In the optical module 342 who in 13A is shown, a light receiving portion (PD 348B for FIR, PD 349B for SIR) and a light emitting section (LED 350B for a long transmission distance, LED 351B for a short Transmission link) with the LSI 347 and it is the light emitting portion and the light receiving portion with a light receiving / emitting lens 343 busy.

The positional relationship in the light receiving / emitting section is in 13B shown. It is the LED that forms 350B for a long transmission distance and the LED 351B each one light emitting portion for a short transmission distance, and they are side by side in the vertical direction at a center of the light receiving / emitting lens 343 arranged. Also, the PD 348B for FIR and the PD 349B for SIR each constituting the light receiving section, positioned such that the light emitting section located at a center of the light receiving / emitting lens 343 is located, is held in between.

It can thus have the same effect as that in the embodiment 7, described above, even then, when a positional relationship between the LEDs and the PDs is changed.

The 14A and 14B FIG. 16 is views showing an example of arrangement of a light receiving / emitting section in an optical communication unit according to a variant 2 of the embodiment 7 described above, wherein FIG 14A and the 14B illustrate a side cross-sectional view and a front view, each of which illustrates the light receiving / emitting section. In this variant 2, the light receiving / emitting section comprises the device-side communication unit 34 like this in 6 shown is an optical module 342 and a light receiving / emitting lens 343 , In the optical module 342 are, as in 14A is shown, the light receiving section (PD 348C ) and the light emitting section (LED 350C ) to the LSI 347 and it is the light receiving section and the light emitting section having a light receiving / emitting lens 343 occupied by a curved shape.

The arrangement of the light receiving / emitting section is as shown in FIG 14B is shown. They are the LED 350C which forms the light emitting portion, and the PD 348C forming the light receiving section, side by side in the horizontal direction at a center of the light receiving / emitting lens 343 intended.

at this variant 2 will only one type of LEDs and a type of PDs use what they can makes a simpler configuration of the light receiving / emitting section to realize. The communication speed does not need for SIR and FIR to be differentiated and the same effect as the one in the embodiment 7 can be achieved, and only to the point that the communication accomplished without the need for power control for a long distance transmission or for a short transmission distance.

The 15A and 15B FIG. 12 is views showing an example of the arrangement of a light receiving / emitting section in an optical communication unit according to a variant 3 of Embodiment 7. FIG. 15A and 15B FIG. 16 is a side cross-sectional view and a front view, each showing the light receiving / emitting section. FIG. In this variation 3, the light receiving / emitting section includes in the device side communication unit 34 the optical module 342 and the light-receiving / emitting lens 343 like this in 6 is shown. In the optical module 342 are, like this in 15A is shown, the light receiving section (PD 348D ) and the light emitting section (LED 350D ) to the LSI 347 and the light emitting portion and the light receiving portion are connected to the light receiving / emitting lens 343 occupied, which has a curved shape.

The positional relationship of the light receiving / emitting section is as shown in FIG 15B is shown. It is the PD 348D representing the light receiving section and the LED 350D representing the light emitting portion, side by side in the vertical direction at a center of the light receiving / emitting lens 343 intended.

Also in this variant 3 becomes merely as in the above-described Variant 2, a type of LEDs and a type of PDs used, so that a simpler Configuration of the light receiving / Emittierabschnitts be realized can. The communication speed does not need for SIR and FIR can be differentiated and it can have the same effect as the one in the embodiment 7, the point that the communication is carried out is excluded can, without the need of a power control for a long transmission distance or for a short transmission distance.

Even though the description of the present invention based on embodiments 1 to 7, it should be noted that various Types of modifications can be realized without affecting the frame and to abandon the teachings of the present invention, as follows is described and claimed, and that such modifications are not excluded from the scope of the present invention.

As described above, in the optical communication unit according to the present invention, a driving force of a driving portion that drives a light emitting portion is incorporated in FIG changed a control section in accordance with a command from a switch section which can give a change to an optical signal which is emitted by the light emitting section. For this reason, it is possible to obtain an optical communication unit that achieves efficiency in using the energy suitable for desired optical communication.

at the optical communication unit according to the present invention becomes an amount of light emitted from the light emitting portion was, as a driving force for changed the driver section, so that it possible is to obtain an optical communication unit which the can reduce optical energy by the efficiency of use the energy suitable for the desired optical communication is improved.

at the optical communication unit according to the present invention becomes a transmission speed an optical signal changed, in the form of a driving force for a driver section, so that it possible is to obtain an optical communication unit, which is a communication speed increase can be suitable by the efficiency of the use of energy for one desired optical communication is improved.

at the optical communication unit according to the present invention the switching section supplies a command for switching a drive force for the control section, if the connection of a device as a destination for the transmission detected so that it becomes possible to obtain an optical communication unit in which the ordinary optical communication is performed, if the connection of the device as a destination for the transfer was not established and, when the connection has been established, can be a change a quantity of light to reduce the optical energy or a change in a transmission speed, to increase a communication speed, be executed.

at the optical communication unit according to the present invention a switch section provides a command to toggle one Driver power for the control section when the connection between a device as a destination for the transmission and an optical cable unit has been detected so that it becomes possible to obtain an optical communication unit in which the ordinary optical communication unit is then executed when the connection between the device as a destination for the transmission and the optical cable unit has not been created and, if the Connection has been created, a change in the amount of light, to reduce the optical energy, or a change in the transmission speed, to make communication faster, run.

at the optical communication unit according to the present invention a connection is detected and a change command signal is asserted output the control section by a sensor in the control section, so that it becomes possible to obtain an optical communication unit in which the switching section in a safe way, a timing or timing of the switching process can be obtained with a simple design.

at the optical communication unit according to the present invention a connection is detected and a command to change a Driver power is applied to the driver section through hardware in outputted to the switching section, so that it becomes possible to have an optical communication unit to receive at the switching section in a secure manner a timing of the switching process with a simple design can receive.

at the optical communication unit according to the present invention an optical signal is received by a light receiving section, so that it possible is to obtain an optical communication unit in which the Communication is not easy from one-way communication by emitting an optical signal, but duplex communication realized with infrared rays by receiving the optical signals can be.

at the optical communication unit according to the present invention are the light receiving portion and the Lichtemittierabschnitt with a same lens, so that it becomes possible to use an optical communication unit to maintain accuracy of duplex communication ensured can be as far as a quantity of light and a transmission speed be provided under the same conditions.

at the optical communication unit according to the present invention becomes a visible light through an optical filter in a light path to the light emitting portion as well as to the light receiving portion cut or filtered out so that it becomes possible to have an optical communication unit to obtain a satisfactory optical communication can be realized by only an infrared ray is received and emitted with a higher frequency as that of the visible light.

at the optical communication unit according to the present invention becomes the collapse of an optical signal from the light emitting section in the light receiving section through a shielding section prevents, within the optical communication unit, in a device to carry out the communication is provided using an optical Signals, so that one emitted optical signal and a received optical signal do not interfere with each other, since the shielding portion between them is provided, and it is possible for this reason, an optical communication unit in which a satisfactory duplex communication is realized can be.

In Connection to the optical communication unit according to the present invention Signals are sent to a device and received by the device, as a communication partner, what about an optical cable unit done so that it possible is to obtain an optical communication unit in which Distance to a device, which serves as a communication partner, arbitrarily set in a state can be where a distance or distance to carry out optical communications the room is kept constant.

In Connection to the optical communication unit according to the present invention Invention is a visible light by means of an optical filter in a light path to the light emitting portion as well as to the Light receiving section cut off or filtered out, so that it is possible to obtain an optical communication unit in which a satisfactory optical communication can be realized by merely an infrared ray is received and emitted with a frequency the higher lies as that of the visible light.

at the optical communication unit according to the present invention is in a signal transmission / reception section coincident with one end of a optical cable is connected, an optical transmission between the device and the optical cable through the light receiving section and the light emitting section performed at the flank or end portion of the connected optical cable, so that it possible is to obtain an optical communication unit in which a communication timing between device can be maintained well, regardless of a length of one optical cable.

In Connection to the optical communication unit according to the present invention Invention includes a Cable a pair of paths for the transmission of optical signals each in different directions so that it becomes possible to realize an optical communication unit in which a duplex communication can be realized within the cable.

at the optical communication unit according to the present invention An optical signal is transmitted from the light-emitting section obstructs a shielding portion, so that the signal is not the light receiving portion enters, so that a emitted optical signal and a received optical signal do not interfere with each other when the shielding section is provided in between, and it is possible for this reason, one to obtain a visual communication unit in which a satisfactory Duplex communication can be realized.

It is in the optical communication unit according to the present Invention converges an optical signal from the device and in the optical Cable output through a first converging lens or converging lens in the light receiving section and it becomes an optical signal transmitted through the optical cable converges and to the device by a second converging lens in the light emitting section sent so that only a small number of components in the light receiving section and is required in the Lichtemittierabschnitt and it out of this Reason possible is to obtain an optical communication unit, in which the entire configuration, the sending process and the receiving process realized by optical signals, simplified and miniaturized can be.

It is in the optical communication unit according to the present Invention a through the device transmitted optical signal is modulated or demodulated and will into the optical cable through a first modulating / demodulating section is sent in the light receiving section and it is on the optical cable transmitted optical signal is modulated or demodulated and is transmitted to the device a second modulating / demodulating section in the light emitting section sent so that it possible is to realize an optical communication unit, in the a desired one Communication speed can be obtained in line with the arrangement of a pulse width of an optical signal, which through the device for one Modulation and demodulation of the signal was sent.

In the optical communication unit according to the present invention, the light receiving section and the light emitting section are populated with a same lens, so that it becomes possible to realize an optical communication unit in which the accuracy of Dup lex communication can be ensured insofar as a quantity of light and a transmission speed are delivered under the same conditions.

In the optical communication unit according to the present invention a circuit is provided which has an available area in accordance with a Communication speed of an optical signal in the light receiving section changes, so that only an area that is extremely suitable for one Communication speed of the optical signal is used and with the help of this feature the effect is achieved that one optical communication unit can be realized, in which the Energy consumption is made more efficient.

at the optical communication unit according to the present invention is provided in the Lichtemittierabschnitt a circuit which an available one Range according to a transmission distance an optical signal changes, so that only an area for a transmission distance an optical signal is extremely suitable, can be used and which achieves the effect with this feature will that one optical communication unit can be obtained, in which the Energy consumption is made more efficient.

It are in the optical communication unit according to the present Invention, the light receiving portion and the light emitting portion with each other integrated and the integrated Lichtempfangs- / Emittierabschnitt is with one piece a converging lens or collecting lens, so that the Lichtempfangs- / Emittierabschnitt can be minimized and achieved with the help of this feature the effect can be that one optical communication unit can be realized in their entire unit can be made even smaller.

Of the Light receiving portion and the light emitting portion in the optical Communication unit according to the present invention comprise a single convergence lens for converging an optical signal from the device as well as the optical cable, so that only a small number of Components in the light receiving section and in the light emitting section is necessary, and it is possible for this reason, an optical communication unit to realize where the entire configuration is a broadcast and a reception of optical signals realized, simplified and minimized can be realized.

These Application is based on Japanese Patent Application No. HEI 9-262544 and No. HEI 10-31332 filed with the Japanese Patent Office on Apr. September 1997 and February 13, 1998, respectively entire content is incorporated herein by reference.

Even though the invention in conjunction with a specific embodiment for the purpose of a complete and clear disclosure, are the attached claims not restricted by but are to be interpreted as having all the modifications and alternative constructions, as will be apparent to those skilled in the art Area are feasible, with include, which is well below the basic Doctrine, as set forth here, fall.

Claims (10)

Optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) in a device ( 2 . 3 ) is provided, which is a communication using optical signals with a second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ) performs as a partner, which optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) comprises: a light emitting section ( 143 . 243 . 343 . 443 . 543 . 643 ) for emitting optical signals; a driver section for driving the light emitting section; a control section ( 141 . 241 . 341 . 441 . 541 . 641 ) for changing a driving force of the driver section; characterized by an engaging portion ( 14A . 24A . 34A . 34B . 44A . 54A . 64A . 64B ) located at a contact area with the second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ) is provided; a switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) located at the engaging portion ( 14A . 24A . 34A . 34B . 44A . 54A . 64A . 64B ) is provided for detecting the connection between the optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) and the second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ), where the switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) a command for the control section ( 141 . 241 . 341 . 441 . 541 . 641 ) for changing a drive force to change from a spatial transfer mode to a double-speed communication mode when the connection is detected. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, in which the control section ( 141 . 241 . 341 . 441 . 541 . 641 ) an amount of light passing through the light emitting section (FIG. 143 . 243 . 343 . 443 . 543 . 643 ) is emitted as a driving force of the driver section changes. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, in which the control section ( 141 . 241 . 341 . 441 . 541 . 641 ) a transmission speed of an optical signal so changes that the transmission speed is set to the double-speed mode when the connection is detected, and that the transmission speed is set to the ordinary-speed mode when the separation of the optical communication unit (FIG. 14 . 15 . 24 . 34 . 54 . 64 ) and the second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ) is detected. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, wherein the switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) a command to switch a driving force to the control section (FIG. 141 . 241 . 341 . 441 . 541 . 641 ) by providing the connection between the optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) and the second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ) is detected. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, wherein the switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) a command to switch a driving force to the control section (FIG. 141 . 241 . 341 . 441 . 541 . 641 ) by providing the connection between the optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ), which in the device serving as the optical signal receiver ( 2 . 3 ), and the second optical communication unit ( 12 . 13 . 22 . 32 . 42 . 52 . 62 ) is detected for transmitting the optical signal. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, wherein the switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) has a sensor for sending a change command signal to the control section ( 141 . 241 . 341 . 441 . 541 . 641 ) by detecting the connection. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, wherein the switching section ( 147 . 247 . 344 . 447 . 547 . 644 ) has a hardware switch for issuing a command to change a driving force to the control section (FIG. 141 . 241 . 341 . 441 . 541 . 641 ) to deliver. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 1, further comprising a light receiving section ( 144 . 244 . 343 . 444 . 544 . 643 ) for receiving an optical signal. The optical communication unit ( 34 . 64 ) according to claim 8, wherein said light receiving section (16) 343 . 643 ) and the light emitting section ( 343 . 643 ) with a same lens ( 343 . 643 ) are occupied. The optical communication unit ( 14 . 15 . 24 . 34 . 54 . 64 ) according to claim 8, further comprising an optical filter ( 14C . 24B . 34C . 44C . 54B . 64C ) for cutting off a visible light on a light path to the light emitting portion (FIG. 143 . 243 . 343 . 443 . 543 . 643 ) as well as to the light receiving section ( 144 . 244 . 343 . 444 . 544 . 643 ).