CH662225A5 - OPTO-ELECTRONIC ARRANGEMENT FOR POWERING AN ELECTRONIC CIRCUIT WITH LIGHT. - Google Patents

Description

With the present invention, the object is now achieved to transmit energy with the aid of light in such a way that this energy is available in electrical form at the end of the transmission path, with a sufficiently high voltage and a high degree of efficiency being achieved for the conversion . The invention relates to an opto-electrical arrangement according to the preamble of claim 1, the characteristics of which are associated with the light source (s) associated with the light source (s) (each) for intermittent emission of light with one or two specific wavelength ^ ) and whose further characteristic is an uninterrupted connection between the converter (s) and the input winding (s) mentioned.

In a particular embodiment of the invention, two light sources of different wavelengths are used, which are operated alternately and which allow the transmitted power to be doubled compared to an arrangement with only a single wavelength.

The invention will now be described using an exemplary embodiment. In the following, “light” also means infrared and ultraviolet radiation in the wavelength range between 0.4 and 20 μm.

Fig. 1 shows the schematic diagram of a transmission system, each with a central-side and a subscriber-side transceiver, between which speech signals can be transmitted in both directions with the aid of light via a glass fiber and from the central-side to the subscriber-side location, feed energy can also be transmitted.

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2 shows the temporal course of an audio frequency signal to be transmitted, a clock signal controlling the central location and the light signals transmitted from the central location to the subscriber location.

In the upper part of FIG. 1, the central-side transceiver 40 and in the lower part the subscriber-side transceiver 41 are shown. LASER diodes 1 and 2 are contained in the central part 40, the diode 1 emitting light with the wavelength XI and the diode 2 emitting light with the wavelength X2 onto the light wavelength multiplexer 3, from where the two types of light according to the light wave Multiplexer 4 and continue to get on the fiber 5. The multiplexer 4 couples light with the wavelength X3 out of the glass fiber 5 and feeds it to the photodiode 6, where it is converted into electrical energy, which in turn is applied to the amplifier 7. This amplifier outputs its output signal to a demodulator 11, and the demodulated signal appears at the output 8.

The two already mentioned LASER diodes 1 and 2 are fed by the two amplifiers 9 and 10, each of which is supplied with an input signal from the pulse duration modulator 16. This modulator consists, for example, of a monostable multivibrator with a time constant that can be influenced and is triggered by a clock signal supplied via 12 and shown in FIG. 2b via a differentiating element 13. This clock signal is rectangular and its frequency is at least twice as high as the highest audio frequency to be transmitted. The differentiator 13 outputs a short pulse to the modulator at the start of each clock pulse. On the basis of each of these pulses, the modulator generates a pulse whose duration in the uninfluenced state of the modulator corresponds to half the period of the clock signal. These pulses are fed directly to the amplifier 9 and to the amplifier 10 via the inverter 15, so that the two amplifiers 9 and 10 alternately emit a signal, these signals connecting to one another without gaps.

A low-frequency modulation signal shown in FIG. 2a is fed via input 19, which influences the duration of the pulses generated on the basis of the clock signal in a positive or negative sense, so that the pulses shown in FIG. 2c are emitted by modulator 16.

While the described central-side transceiver 40 is fed from any voltage source, the subscriber-side transceiver 41 is supplied with both the supply and the signal via the optical fiber 5. This glass fiber leads to the light wavelength multiplexer 20, where a signal of wavelength X3 originating from the light emitting diode 21 is coupled in. The signal arriving via the optical fiber 5 is further fed to the light wavelength multiplexer 22, where the signals with the two wavelengths XI and X2 are separated. These two signals are fed to the photodiodes 23 and 24, which convert them into electrical power and feed them to the windings 25 of a transformer 35 in push-pull. Further push-pull windings 26 of the transformer form part of a generally customary rectifier circuit which also includes the two diodes 27, the resistor 28 and the capacitor 29 and which supplies supply energy for supplying a pulse generator 30 described later and optionally an amplifier 31.

Another winding 32 of the transformer 35 is connected to a receiver 33 via an amplifier 31. If the signal emitted by the transformer is large enough, the amplifier 31 can be omitted.

The output signal of a microphone 34 is fed to a modulatable pulse generator 30. The pulses emitted by this pulse generator are modulated with the voltage emitted by the microphone 34. In principle, different types of modulation are possible; from the standpoint of

From an energy consumption perspective, pulse position modulation (PPM) is best. The pulse signal emitted by the generator 30 is fed to the light-emitting diode 21, which generates light of the wavelength X3. The light pulses are coupled into the glass fiber 5 with the aid of the light wavelength multiplexer 20.

When the arrangement is at rest, i.e. as long as no modulation signal is fed to the central transceiver, the modulator 16, as has already been briefly mentioned, generates pulses with a duration corresponding to half the period of the clock signal. Since these pulses are triggered by the clock signal, they are the same length as the pauses in between, and the output signal of the modulator 16 corresponds to the clock signal according to FIG. 2b. Druch the effect of the inverter 15, the two amplifiers 9 and 10 each have the same length of signal, whereby the two laser diodes 1 and 2 are driven alternately and without time gaps, which alternately light from the wavelengths XI and X2 the multiplexer 3 and feed from there via the multiplexer 4 of the glass fiber 5.

Via the multiplexer 20, the alternately two-wavelength light now reaches the multiplexer 22, at the two outputs of which light of a single wavelength occurs intermittently. The two signals occurring in push-pull are fed to the photodiodes 23 and 24. The voltage emitted by the two diodes is transformed to a higher voltage via the windings 25 and 26 of the transformer 35, then rectified and screened and fed to the pulse generator 30 and the amplifier 31 as a supply.

As has been stated earlier, a tone-frequency signal supplied at input 19 influences the pulses emitted by modulator 16, so that the course of the light pulses corresponds to the course shown in FIG. 2c. It can be seen from FIGS. 2b and 2c that the transition from the wavelength X2 to XI always coincides with the start of the pulses of the clock signal 12 shown in FIG. 2b, while the transition from the wavelength XI to X2 towards the end of the pulses of the clock signal is shifted in time in a negative or positive sense.

A bipolar square-wave signal is produced on the winding 32 of the transformer 35, which corresponds to the signal shown in FIG. 2c. In relation to one of the polarities, this signal represents a signal modulated in the pulse width. The spectrum of this signal contains, in addition to the audio frequency signal fed in at input 19, also mixed products of this signal with the clock signal 12. Since the frequency of the clock signal is at least twice as high as the highest tone frequency to be transmitted is used by the receiver 33 as a low-pass filter, and the mixed products given to the receiver have no effect, so that only the audio frequency signal is reproduced.

The signal emitted by the pulse generator 30 and modulated by the output signal of the microphone 34 is fed to the light-emitting diode 21, where it is converted into light pulses with the wavelength X3. This light reaches the glass fiber 5 via the multiplexer 20 and is in turn coupled out by the multiplexer 4 and applied to the photodiode 6. This diode generates voltage pulses which are amplified in the amplifier 7 and demodulated in the demodulator 11. The output signal 8 of the demodulator then corresponds to the output signal of the microphone 34.

In the exemplary embodiment listed, if the transformation ratio of the transformer is set to approximately 1: 5, an electrical power of approximately 100 | xW at 2 V voltage can be obtained at the end of the transmission path.

For a relatively short length of the fiber optic cable of up to 200 m, inexpensive light sources are sufficient

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GaAs light-emitting diodes (LED) with 860 and 940 nm wavelength, while silicon photodiodes are suitable as converters on the receiving side.

For a long transmission path of up to 1000 m, in order to achieve the same output power at the end, either the power or the wavelength of the light sources must be increased. The increase in wavelength has an increase in performance because the attenuation of the light guide in relation to the length decreases. The first-mentioned measure can be carried out, for example, by using a GaAs / GaAlAs LASER diode with a wavelength of 387 nm and a higher power than light-emitting diodes as the light source. The second measure can be carried out using an InGaAsP light-emitting diode with a wavelength of 1300 nm. On the receiving side, a silicon photodiode is preferably used as a converter for the shorter wavelength and a GaAs photodiode for the longer wavelength. The two measures can preferably be combined by using two different types of light sources and converters in the same arrangement.

Since the prices of the light sources in the variants described for a short and a long light guide differ by orders of magnitude, the light sources listed in the variant for long conductors are uneconomical for short conductors.

The invention is of course not tied to the exemplary embodiment. It can also be used if there is a separate light guide for each traffic direction or if the light transmitting the feed is not passed on via a light guide 5. This latter case can be considered for the supply of a galvanically fully insulated amplifier, which is located at the supply source. If the light is transmitted in two ways, the same wavelength can be used for both cycles.

The invention is also not tied to the alternate generation of light of different wavelengths. It is essential that the light of a certain wavelength is transmitted intermittently and that a light converter acts directly on a transformer.

15 Light sources consisting of a combination of different LASER diodes and controllable light filters have become known, which emit light of different wavelengths depending on the control. Instead of two light sources and a multiplexer, such a combination can also be used.

The use of LASER diodes and light generating diodes (LED) as light generators and the use of photodiodes to convert light into electrical energy are only to be considered as examples. The invention can basically be applied to all types of light sources and light evaluators.

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Claims (12)

662 225 1. Optoelectronic arrangement for feeding an electronic circuit, in which arrangement the feed energy in the form of light is transmitted between at least one light source (1, 2) and at least one light converting converter (23, 24) into electrical energy, whereby Energy emitted by this converter is intermittently fed to at least one input winding (25) of a transformer (35), transformed to a higher voltage by this transformer (35) and then further processed, characterized by the switching means (12, 16) assigned to the light source (s) , 15), which cause the light source (s) (each) to emit light intermittently with one or two specific wavelength (s) (XI, X2) and by means of an uninterrupted connection between the converter (s) mentioned and the input winding (s) (25) mentioned. 2. Optoelectronic arrangement according to claim 1, in which information (19, 33) is transmitted with the aid of light in addition to feed energy and in which the switching means (15, 16) assigned to the light source (s) (1, 2) , 11) carry out the respective change of the light generation from a first (X2) to a second (XI) state in a regular cycle, characterized in that the said switching means (15, 16, 11) the times of the respective change from the second (XI ) in the first (X2) state of the light generation so dependent on the information to be transmitted that the information is transmitted in the form of pulse-duration modulation. 2nd PATENT CLAIMS 3. Optoelectronic arrangement according to claim 1, characterized by two transducers (23, 24), by two input windings (25) of the transformer (35), to which the two transducers are connected in push-pull and by designing the light source (s) and the circuit means (12, 16, 15) controlling them in a manner according to which the two transducers are alternately supplied with light of the wavelength assigned to them. 4. Optoelectronic arrangement according to claim 3, characterized in that the light source (s) (1, 2) alternately generates light of different wavelengths (XI, X2) and that each transducer (23, 24) has light of different wavelengths converts. 5. Optoelectronic arrangement according to claim 4, characterized in that the light of both wavelengths (XI, X2) is transmitted via a single light guide to the transducers (23, 24) and with the aid of a light wavelength multiplexer (22) is distributed to both transducers. 6. Opto-electronic arrangement according to claim 5, characterized in that two light sources (1, 2) are present, which generate light with different wavelengths (XI, X2) and that the light generated by the two light sources by a light wavelength multiplexer ( 3) summarized and transmitted to the transducers (23, 24) via a single light guide (5). 7. Opto-electronic arrangement according to claim 5, characterized in that a single light source is present, which alternately generates light with two different wavelengths (XI, X2). 8. Optoelectronic arrangement according to one of the claims 3 to 7, characterized in that the said switching means (12, 16, 15) cause the light source (s) to emit light in a practically continuous manner. 9. Optoelectronic arrangement according to claims 2 and 8. 10. Opto-electronic arrangement according to one of the claims 1 to 9, characterized in that the light sources (1, 2) are lasers. 11. Optoelectronic arrangement according to one of the claims 1 to 6, 8 or 9, characterized in that the light sources (1, 2) are light-emitting diodes (LED). 12. Opto-electronic arrangement according to one of the claims 1 to 11, characterized in that the transducers (23, 24) are photodiodes. It is generally known to transmit not only information but also feed energy via light guides, for example from a telephone exchange to a subscriber station. In the process, light energy is fed into a light guide, preferably an optical fiber, by a light generator, received by one or more opto-electrical converters at the subscriber station and converted into electrical energy. With such an arrangement, it is disadvantageous that the voltage emitted by the photodiodes used as converters is only approximately 1 V, while most electronic circuits require a higher supply voltage. At this low supply voltage, the known circuits have a very poor efficiency or cannot be operated at all. It is therefore necessary to increase the voltage delivered by the converters. It is known to achieve such an increase by means of a conventional chopper circuit with subsequent transformation and rectification (DC-DC converter), but the disadvantages of a low supply voltage mentioned above for the operation of the chopper remain. It is also known to connect a plurality of photodiodes in series, a difficulty being to distribute the light arriving via the light guide more or less uniformly and with little loss over these photodiodes. In known arrangements, additional information is transmitted with the transmitting and receiving devices transmitting the feed energy, by dividing the light energy into pulses which are long with respect to the gaps and are modulated in length or phase with the information. As a result of the gaps mentioned, the power which can be transmitted in this way is smaller than it could be if light were transmitted continuously.