JPH04161029A - Pulse light feeder - Google Patents

Abstract

PURPOSE:To securely supply power even during data communication and improve data communication efficiency by equipping a signal processor with a pulse light transmitter which produces pulse light phase-modulated with codes having different high-level time interval. CONSTITUTION:Pulse light, the phase of which is modulated according to bi- phase codes different high-level time intervals in a specified period S, is transmitted to a signal processor 10. Thereby constant power is securely supplied to a terminal device 20 without decreasing while data are transmitted from the signal processor 10 to the terminal device 20. Therefore, power is supplied and data are continuously transmitted to the terminal device 20 at the same time. Moreover, no optical fiber is required.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention (Industrial Application Field) The present invention relates to a pulsed light power supply device that transmits pulsed light from a signal processing device to a terminal device to perform power supply and data transmission.

(Prior Art) FIG. 9 is a block diagram of such a pulsed light power supply device. The signal processing device A is equipped with a power supply 1, and a semiconductor laser 2 is connected to this power supply 1. - On the other hand, the terminal device B is equipped with a photodiode 3 and connected to the primary coil of a transformer 4.

An electronic device 5 is connected to the secondary coil of the transformer 4. Note that the transformer 4 also has the function of impedance matching between the photodiode 3 and the electronic device 5. An optical fiber 6 is arranged between the semiconductor laser 2 and the photodiode 3.

With such a configuration, the semiconductor laser 2 emits pulsed laser light using the pulsed voltage supplied from the power supply 1. This pulsed laser light is emitted for a predetermined period with a period C as shown in FIG. Note that in the figure, the shaded area indicates the period during which the pulsed laser beam is output. This pulsed laser light is transmitted through the optical fiber 6 and is received by the photodiode 3. This photodiode 3 photoelectrically converts the received pulsed laser light to obtain a voltage signal. Transformer 4 boosts this voltage signal and connects it to electronic equipment! Supply to 5. That is, power is supplied to the electronic device 5.

On the other hand, when performing data communication from the signal processing device A to the terminal device B, the signal processing device A stops supplying power by the pulsed laser beam, and performs data communication in a period Q as shown in FIG.

This data communication transmits data using the NRZ method.

However, when data communication is performed while supplying power by pulsed laser light, the supply of pulsed laser light becomes intermittent, so a sufficient amount of light is not transmitted, and the power supplied to terminal device B gradually decreases. do.

As a result, the electronic device 5 no longer operates satisfactorily.

To solve this problem, it is sufficient to supply a sufficient amount of light to the terminal device B in advance, but since the life of the semiconductor laser 2 is proportional to the second to fourth power of the emitted energy, increasing the amount of light emitted by the semiconductor laser 2 Lifespan becomes extremely short. Therefore, data communication is performed using a voltage V that is at a level that allows the electronic device 5 to operate.
It must be within the period in which 0 is supplied. For this reason, data communication efficiency is low.

(Problems to be Solved by the Invention) As described in (2) above, the power supplied to the terminal device during the data communication period decreases, and the efficiency of data communication deteriorates.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a pulsed light power supply device that can reliably supply power even during data communication and improve the efficiency of data communication.

[Structure of the Invention] (Means for Solving the Problems) The present invention supplies power from a signal processing device to a terminal device and also transmits and receives data by transmitting and receiving pulsed light between the signal processing device and the terminal device. In a pulsed light power feeding device that attempts to achieve the above object, at least the signal processing device includes a pulsed light sending means for obtaining pulsed light by phase modulating the high level period using different codes.

(Function) By providing such a means, at least the pulsed light sending means of the signal processing device sends pulsed light phase-modulated according to different codes of high-level periods within a predetermined cycle to the terminal device.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a configuration diagram of a pulsed light power supply device. A terminal device 20 is connected to the signal processing device] 0 via an optical fiber 30 for optical energy transmission and an optical fiber /<=31 for signal transmission.

The signal processing device 10 includes a signal processing section 11. This signal processing section 11 has a function of sending out a pulse signal that becomes high level at every predetermined period and performing data communication using a biphase code phase shift modulation method. As shown in Fig. 2, this bi-phase code has a signal R that changes from a high level to a low level within a period S and whose mark rate is 50% as "1", and a signal R that changes from a low level to a low level within the same period S. The signal E that changes to a high level and has a mark rate of 50% is set to 0''. Therefore, the signal processing section 10 combines the signals R and E and sends out data consisting of "1" and "0".

A control drive circuit 13 is connected to the signal processing section 10 via an adder 12. This control drive circuit 13 has a function of receiving data from the signal processing section 10 and driving the semiconductor laser 14. The pulsed laser beam output from the semiconductor laser 14 is arranged so as to be incident on the optical fiber 30. Further, a part of the pulsed laser light output from the semiconductor laser 14 is incident on a photodiode 15 for automatic light amount control. This photodiode 1
An electric signal corresponding to the amount of received light outputted from 5 is input to an adder 12 through an amplifier circuit 6.

Further, a separation and demodulation circuit 18 having a photodiode 17 is connected to the signal processing section 11 . The photodiode 17 is arranged at the output end of the optical fiber 31 and has the function of receiving a light pulse signal transmitted through the optical fiber 31 and converting it into an electric signal. The separation/demodulation circuit 17 has a function of separating the electric signal obtained by photoelectric conversion of the photodiode 18 into signal components.

On the other hand, the terminal device 20 has a function of processing the detection data of the physical quantity detected by the detector 21 according to the data sent from the signal processing device 10. Specifically, it has the following configuration. A photodiode 23 is connected to the primary coil of the transformer 22 . This photodiode 23 is arranged at the output end of the optical fiber 30 and converts the pulsed laser light transmitted through the optical fiber 30 into an electrical signal. A comparator 25 is connected to the secondary coil of the transformer 22 via a rectifier circuit 24 . This comparator 25 has a function of supplying the voltage to each circuit constituting the terminal device 20, such as the control circuit 26, when the voltage level appearing in the secondary coil of the transformer 22 is higher than a predetermined level. Further, a signal demodulation circuit 27 is connected to the secondary coil of the transformer 22. This signal demodulation circuit 27 demodulates the electrical signal appearing in the secondary coil of the transformer 22 into data consisting of "1"O", and then sends it to the control circuit 2.
It has a function to send to 6.

This control circuit 26 is connected to a signal processing section 28 and a modulation circuit 29, and has a function of controlling the operation of these signal processing section 28 and modulation circuit 29. The signal processing unit 28 has a function of processing the detection data from the two detectors according to the received data. The modulation circuit 29 is the signal processing section 28
It has a function of receiving the data processed by the control circuit 26 in response to a command from the control circuit 26, modulating the data into an optical pulse signal, and operating the semiconductor laser 32.

Next, the operation of the apparatus configured as described above will be explained.

First, the operation when data communication is stopped will be explained. The signal processing unit 10 outputs data that repeats high level and low level at a period S. In this case, the mark rate of this data is 50%. This data is sent to the control drive circuit 13 through the adder 12. This control drive circuit 1
3 receives data and drives a semiconductor laser]4. As a result, the semiconductor laser 14 repeatedly outputs pulsed laser light with a period S as shown in FIG. This pulsed laser light enters the optical fiber 30 and is transmitted to the terminal device 20. At this time, a part of the pulsed laser light output from the semiconductor laser 14 is received by the photodiode 15, and the photodiode 15 outputs an electric signal according to the amount of light received. This electrical signal is fed back to the adder 2 through the amplifier circuit 16. Thereby, the control drive circuit 13 controls the laser output intensity of the semiconductor laser 14 to be constant.

The pulsed laser light transmitted through the optical fiber 30 is received by the photodiode 23 of the terminal device 20 and converted into a voltage signal. This voltage signal is boosted by a transformer 22 and sent to a comparator 25 through a rectifier circuit 24. If the voltage level appearing on the secondary coil of the transformer 22 is higher than a predetermined level, the comparator 25 transfers the voltage to the control circuit 26.
It is supplied to each circuit constituting the terminal device 20 such as.

In this state, the signal processing unit 28 collects detection data from the detector 2].

Next, the operation during data communication will be explained.

The signal processing device 11 is designated by each symbol "1" shown in FIGS. 2 and 3.
” Data communication is performed by a bi-phase code phase shift modulation method using “0”. For example, when sending data “010...”, the signal processing unit 10 performs low level, high level, and next It sends out a signal that goes high level, low level in a cycle S, and then goes low level, high level, and so on in the next cycle S. This signal is sent to the control drive circuit 13 through the adder 12, so that the semiconductor laser 14 emits pulsed laser light at the timing shown in FIG.

This pulsed laser light is transmitted through the optical fiber 30 and sent to the terminal device 20 in the same manner as described above.

This pulsed laser light is received by a photodiode 23, converted into a voltage signal, boosted by a transformer 22, and sent to a comparator 25 through a rectifier circuit 24. If the voltage level appearing on the secondary coil of the transformer 22 is higher than a predetermined level, the comparator 25 converts the voltage to a control circuit 26.
It is supplied to each circuit constituting the terminal device 2°.

Further, the voltage appearing in the secondary coil of the transformer 22 is sent to the signal demodulation circuit 27. This signal demodulation circuit 27 converts the electrical signal appearing in the secondary coil of the transformer 22 into "010...
. . ” and sends it to the control circuit 26. This control circuit 26 receives data from the signal demodulation circuit 27, determines its contents, and issues a command according to the data contents. For example, the control circuit 26 sequentially passes each detection data collected by the signal processing section 28 to the modulation circuit 29.

This modulation circuit 29 operates the semiconductor laser 32 according to each detection data. Thereby, the pulsed laser light output from the semiconductor laser 32 is transmitted through the optical fiber 31 and received by the photodiode 17 of the signal processing device 10. This photodiode 17 sends an electric signal corresponding to the amount of light received to a separation/demodulation circuit 18 . This separation/demodulation circuit 18 separates the electrical signal from the photodiode 18 into signal components and sends the separated signals to the signal processing section 11 . This signal processing section 11 receives the signal and executes predetermined processing.

In this way, in the above embodiment, the signal processing device 10
Since pulsed light is phase-modulated in accordance with bi-phase codes with different level periods within a predetermined period S, the data communication is performed from the signal processing device 10 to the terminal device 20. Power can be supplied to the terminal device 20 inside the terminal device 20, and this power can also be reliably supplied at a constant level without decreasing. Therefore, power supply to the terminal device 20 and data communication can be performed simultaneously, and data communication can be performed continuously. Further, there is no need to separately provide an optical fiber or the like.

Note that the present invention is not limited to the above-mentioned embodiment (it may be modified without changing the gist thereof. For example, the signal demodulation means in the terminal device 20 may include a photodiode 40 as shown in FIG. and an optical signal demodulation circuit 41.The photodiode 40 is connected to the optical fiber 3.
It is arranged so as to receive a part of the optical pulse signal that transmits 0. In this case, a part of the optical pulse signal is transmitted from the optical fiber 30 to the photodiode 40 by using an optical splitter such as a star coupler or a beam splitter. Further, the optical signal demodulation circuit 41 has a function of receiving an electrical signal from the photodiode 40, demodulating it into a 1 "0" signal, and sending it to the control circuit 26.

Furthermore, in order to prevent the frequency spectrum from expanding due to the content of communication data, the same code may be transmitted twice as shown in FIG. That is, for example, when the signal processing unit 11 transmits the data "ro 101...", it converts it into "roollooll..." and transmits it. This reduces the spread of frequency components due to data.

Further, a plurality of terminal devices 20 may be connected to the signal processing device 10. In this case, the output end of the optical fiber 30 has an optical splitter 4 such as a beam splitter as shown in FIG.
2 is connected.

Further, the code used for data communication is not limited to the bi-phase code, and as shown in FIG. 8, the code "1" and "0" may be formed so that the high level periods are different within the period S.

It is possible to provide a pulsed light power supply device that can reliably supply power even during communication and improve the efficiency of data communication.

[Brief explanation of drawings]

1 to 4 are diagrams for explaining one embodiment of the pulsed light feeding device according to the present invention, in which FIG. 1 is a configuration diagram, and FIGS. 2 and 3 are waveforms of biphase codes. Figure, 4th
The figure is a diagram for explaining the operation of data communication, Figures 5 to 7 are diagrams for explaining other embodiments, Figure 8 is a diagram showing other code examples, and Figures 9 and 10 are diagrams for explaining other embodiments. The figure is a diagram for explaining the prior art. 10... Signal processing device, 11... Signal processing section, 12
... Adder, 13... Control drive circuit, 14... Semiconductor laser, 15... Photodiode, 16...
Amplifier circuit, 17... Photodiode, 18... Separation and demodulation circuit, 20... Terminal device, 21... Detector,
22...Transformer, 23...Photodiode, 2
4... Rectifier circuit, 25... Comparison circuit, 26... Control circuit, 27... Signal demodulation circuit, 28... Signal processing section, 29... Modulation circuit, 30゜31-゛ optical fiber , 32...photodiode. Applicant's agent Patent attorney Takehiko Suzue Figure 5 Figure 6 Figure 1 L
J2゜

Claims (1)

[Claims] In a pulsed light power feeding device that supplies power from the signal processing device to the terminal device and also sends and receives data by sending and receiving pulsed light between the signal processing device and the terminal device, at least the signal processing device has a high level What is claimed is: 1. A pulsed light power feeding device comprising a pulsed light transmitting means that obtains the pulsed light by performing phase modulation using codes having different periods.