HU200866B - Circuit arrangement for wireless great-distance data transfer between nodes with signal lamps - Google Patents

Abstract

Field of the Invention The present invention relates to a switching arrangement for wireless digital data transmission between signal light nodes with a transmitter and receiver, the transmitter comprising an input encoder circuit (3) having parallel useful signal input and synchronous signal input, and the output of the input coding circuit (3) with an oscillator (5). connected to the input of a connected FSK modulator (4), and the FSK modulator (4) is connected to an infrared (8) connected to the optical system (9) via a power amplifier (7) on a galvanic isolation unit (6), the output of which is the transmitter output, the receiver ( And 2) a photodiode (11) connected to the optical system (10) for receiving a signal transmitted by said infrared emitter (8) comprises a signal processing unit connected to its output. It is an object of the present invention that the signal processing unit is the scope of the description: 4 pages, the input of Fig. 3 is a preamplifier connected to a mixing stage (13) coupled to the oscillator (14), and the mixing stage (13) is a selective KF amplifier (15) of 51 Hz bandwidth. the frequency modulator (16), the low pass filter (17), the comparator (18), and the isolation unit (19) are connected to the decoder input (20) of the signal that is repeatedly reproduced at the signal input of the transmitter, and the transmitter carrier frequencies are 29131 and 29080 Hz; -and = 29105 Hz, while on the receiving side the mixer is formed with a stirring frequency of 2894 Hz, and Q of the low pass filter (17) is determined by the mixing frequency as follows: Q = fkcver € si / lane = 2894/51. (Figures 1, 2) TÜFO-Q-CH Figure 2 HU 200 866 B -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for long-distance wireless data transmission between signal node nodes, which signal circuits are located at a distance of 800-2000 m with a circuit arrangement, or computer units, etc. and data transmission provides good data transmission even in noisy environments.

Some data transmission systems are configured to transmit information through cables, which means that each data transmission path must be fitted with cables, which has the disadvantage of being both expensive to install and relatively large in import material. These relationships cannot be expanded in a short and arbitrary manner without disturbing or disturbing the external environment.

Another known solution is HU-193.227. s. U.S. Patent No. 4,123,129, wherein data transmission is by infrared signal transmission, thereby eliminating some of the cabling and providing data transmission over a relatively long range. In this arrangement, a frequency selective system is used, where the information is contained in the frequency fm of the transmitted signal. Frequency is detected by so-called tracking filters applied on the receiver side after the FSK demodulator. The system is relatively broadband, and the signal-to-noise ratio, such as range, is achieved by

After a FM demodulator of unit 9, a wide-band tracking filter selects the frequency of its discrete fm. The increase in signal-to-noise ratio in this solution can be achieved in proportion to the relatively high noise bandwidth of the FM demodulator and the low noise bandwidth of the subsequent filter. Thus, this solution requires the use of a complex filter system for which simple circuit elements or commonly used operational amplifiers are not suitable.

It has been an object of the present invention to provide optical signal-to-noise ratios so that the range can be increased by simpler circuits. The invention has led us to realize that the range can be increased by using a narrowband system from the outset. Thus, if the receiver side has a very narrow frequency band that passes useful information, the system will greatly suppress broadband noise, thereby increasing the signal-to-noise ratio and range and eliminating the need for complex circuit filters.

Accordingly, the invention provides a circuit arrangement for wireless digital data transmission between signal lamp nodes, wherein the transmitter comprises an input encoded circuit having parallel useful signal inputs and a synchronous signal input, and an input encoder circuit output coupled to an oscillator FSK modulator. a galvanic isolation unit coupled via a power amplifier to an infrared receiver connected to an optical system whose output is a transmitter output, and the receiver comprises a processing unit connected to the output of the photodiode configured to receive the signal emitted by said infrared system.

The essence of the circuit arrangement according to the invention is that the input of the signal processing unit is a preamplifier which is connected to a mixing stage connected to an oscillator and the mixing stage is connected via a 51 Hz bandwidth selective KF amplifier, frequency modulator, low pass filter, comparator connected to the input of the decoder which reproduces the signal, the transmitter carrier frequencies are 29131 and 29080 Hz, its head = 29105 Hz, while the receiver side is equipped with a mixer frequency 2894 Hz, and the low pass filter Q according to the mixing frequency below define:

= mixing / bandwidth = 2894/51.

Also preferred is an embodiment of the invention wherein the input of the encoding circuit is a multiplexer connected to one output of a multiplexer controller coupled to an output of a multiplexer controller connected to an output of an FSK modulator comprising a distribution circuit, a main distribution circuit, and a distribution circuit; connected to a memory, which together with the output of the modulator is connected via a logic gate circuit to one of the inputs of the pre-distribution circuit, the main distribution circuit and the post-distribution circuit.

The circuit arrangement according to the invention will now be described in more detail by means of an exemplary embodiment in the accompanying drawings. The

FIG. 1 is a block diagram of a transmitter configured for a circuit arrangement according to the invention, and FIG. 1 is a block diagram of a receiver configured for the same circuit arrangement;

Figure 3 shows a more detailed circuit diagram of the transmitter.

Thus, Fig. 1 is a block diagram of a transmitter having an input of an encoding circuit 3 having seven inputs, i.e. for Do ... D6 signals and a synchronizing Dsyn signal. The encoding circuit 3 converts the parallel incoming signals, which are digital signals, into a serial bit sequence of appropriate frame size for transmission. The output of the encoding circuit 3 is led to an FSK modulator 4 which keypads the frequency of an oscillator 5, i.e. assigns a frequency f2 to logic 1 and fi to logic 0. This is accomplished by means of an oscillator 5 connected to the FSK modulator 4. The output of the FSK modulator 4 displays an FSK signal f = f 1 to f2, which is connected to a power amplifier 7 via a disconnector unit 6, which is connected to an optical system 9 via an infrared radiator 8. In the exemplary embodiment, the infrared emitter 8 is a light emitting diode which emits infrared analogs to the input signal through an OPEMUS type capacitor lens as an optical system 9.

The coding circuit 3, the FSK modulator 4, the oscillator 5 and the disconnector unit 6, which are galvanically disconnected optocouplers, are e.g. outdoor, such as a pole.

The block diagram of receiver 2 is shown in Figure 2. The optical system 10 of the receiver 2, preferably also a lens or lens system, is connected to the photodiode 11, the output of which is connected to a mixing stage 13 via a preamplifier 12 which is also coupled to an oscillator 14. The output of the mixing stage A13 is led to a low-pass filter 17 on a selective KF amplifier 15 and a frequency demodulator 16. The output of the low-pass filter 17 is connected via a comparator 18, with an isolation stage 19, to the input of a decoder circuit 20, which outputs a signal corresponding to the original signal sequence.

Fig. 3 shows a more detailed exemplary embodiment of the transmitter 1, which shows an encoding circuit 3, an FSK modulator 4 and an oscillator 5 and includes an oscillator 21, preferably a quartz oscillator, with an output of 1/4 and 4/4 respectively. 1/57 and 1/57, respectively, through a 1/5 frequency distribution circuit 22 that provides a 1/5 frequency division. 1/59, ill. 1/74 to 23 main distribution circuits implementing frequency division, then 1/1454, respectively, with tin. 1/1456 is connected to a 24 splitter circuit implementing frequency division. The sub-distribution circuit 24 is connected to the inputs of the sub-distribution circuit 22 and the main distribution circuit 23 via a gate circuit 29, respectively, to the output of the unit and to the storage input 28. Namely, the sub-distribution circuit 24 is provided with another input connected to the multiplexer controller 26, which is connected to the multiplexer 25 on the one hand and the data inputs of the transmitter input signal 1 on the other hand to the Manchester encoder 27 led and its output is connected to the input 28 of the container.

The apparatus according to the invention operates as follows: The FSK modulator 4, the detailed circuit diagram of which is shown in FIG. 3, includes, inter alia, 21 oscillators which are crystal oscillators at 1689 KHz.

Its output signal controls the distribution circuit 22, which, depending on the signal levels at its input, is 1/4 or 2, respectively. Performs a 1/5 split. The output signal of the distribution circuit 22 is output to the main distribution circuit 23, which is 1/57, 1/59, respectively, depending on the signal levels at its input. Performs a division of 1/74.

The main distribution circuit 22 drives the after-distribution circuit 24, which has a programmable 1/1254 pitch ratio. 1/1456.

The output of the post-strain circuit 24, the output of the multiplexer controller 26, is connected to the output of the multiplexer controller 26 with a phase shift UCC and SC clocked with a nominal period of 25 ms.

The Manchester encoded signal is written to the memory 28, which is a memory D and whose signal and luminance signal at the output of the distribution circuit 24 is controlled via the outputs of the logic gate network 29 by a splitter 4 (pre- and post-distribution) acting as FSK modulator 4.

The power amplifier input 7 has a TIL II optocoupler disconnector 6 which receives a Manchester code modulated serial data signal. If the incoming signal hangs at level 1, it drives the infrared light 8, i.e. the diode, as a clock generator.

Conversely, if the incoming signal is low, the infrared diode will not broadcast.

The receiver 12 preamplifier 12 receives the Manchester coded infrared beam via optical system 1 and photodiode 11. The amplified modulated data signal appearing at the output of the preamplifier 12 goes to a mixing stage 13 which, with the signal of the oscillator 14, reduces the incoming signal to a center frequency of 2894 Hz. The KF signal appears at the output of the mixing stage 13. The selective amplifier KF 15, the frequency demodulator 16, the low pass filter 17 and the comparator 18 are connected in series to the output of the mixing stage 134.

The 6 selective amplifier μΑ is a highly selective (Q = 60 B = 50 Hz) active bandpass circuit composed of 747 circuits. The already demodulated signal goes to a low pass filter 17 formed by an operational amplifier µΑ 747, and the reset data signal appears at the output of the comparator 18, and then the decoupling unit 19 through the decoder 20 at the output.

The circuit arrangement according to the present invention is limited in its function of transmitting information so that narrowband FSK modulation is possible. The narrowband system is capable of selectively transmitting the payload and the optical system connected to it eliminates interference and reduces electronics noise due to low bandwidth.

However, narrow bandwidth cannot be achieved at the receiver frequency, so the receiver has a mixing stage 13 which mixes the incoming signal to 2894 Hz.

At receiver 2, selectivity was achieved with active filters.

On the transmitter side, the carrier frequencies are 29131 and 29080 Hz, i.e. Fo = 29105 Hz, and the frequency strokes are 29131-19080 = 51 Hz.

On the receiving side, i.e. receiver 2, the bandwidth is 51 Hz. From this data, we determine how large Q is for such an efficient system.

Q = fo / B 29105/51 = 570.7

However, a filter with a Q of 2894/51 = 56.7 is sufficient at the reduced frequency.

The circuit arrangement according to the invention is easy to install, simple in design and insensitive to environmental disturbances.

Claims (2)

PATENT CLAIMS A circuit arrangement for wireless digital data transmission between signal node nodes with transmitter and receiver, wherein the transmitter (1) comprises an input encoded circuit (3) having parallel useful signal inputs and a synchronous signal input and an output encoder (3) output oscillator (5). connected FSK modulator (4) -3GB 200866 Β input and the FSK modulator (4) is connected via a galvanic isolation unit (6) via an power amplifier (7) to an infrared (8) connected to an optical system (9), the output of which is the transmitter output, the receiver (2). and a photodiode (11) associated with the optical system (10) for receiving the signal emitted by said infrared (8), comprising a signal processing unit connected to its output, characterized in that the input of the processing unit is a preamplifier connected to an oscillator (14) 13) is connected and the mixing stage (13) has a signal similar to the signal connected to the transmitter input via a 51 Hz bandwidth selective KF amplifier (15), frequency modulator (16), low pass filter (17), comparator (18) and disconnector (19). connected to the input (20) of the reproducing decoder, further BBA the transmitter carrier frequency of 29 131 and 29 080 Hz value, fo-ja = 29105 Hz, while the vevő6 side of the mixer is constructed 2894 Hz mixing frequency, and the low-pass filter (17) Q is adjusted in the mixing frequency is taken into account is determined as follows: Q = fever & bandwidth = 2894/51. A circuit arrangement according to claim 1, characterized in that the encoder circuit input is formed by a multiplexer (25), which is an FSK modulator (4) comprising a distribution circuit (22), a main distribution circuit (23) and a distribution circuit (24). connected to one of the outputs of a multiplexer controller (26) coupled to an output of a secondary distribution circuit (24) and each of the multiplexer controller (26) connected to a storage (28) via a Manchester encoder (27) with an output of a modulator (4) together, a logic gate circuit (29) is connected to one of the inputs of the pre-distribution circuit (22), the main distribution circuit (23) and the secondary distribution circuit.