CS214934B1 - Wiring a modulator for data transmission - Google Patents

Abstract

The invention relates to a data transmission modulator circuit suitable for use in portable and stationary devices using phase shift keying. The circuit allows for maximum use of integrated circuits. Its essence lies in the fact that the resulting signal is obtained by synthesizing rectangular voltage waveforms in a simple system of logic circuits and is adjusted to the desired time waveform by limiting the frequency spectrum with a simple filter at the modulator output. The synchronization of the carrier and data signals is ensured by the fact that the carrier generator simultaneously serves as a source of clock pulses for data retrieval from the memory. The synthesis of rectangular voltage waveforms is ensured by three binary frequency dividers and a non-equivalence circuit. In the simplest case, a simple RC low-pass filter is sufficient to limit the frequency spectrum at the output. The connection is particularly suitable for simple modems with transmission in the acoustic frequency band, for example over telephone lines or radiotelephone connections.

Description

The invention relates to the connection of a data transmission modulator suitable for use in both portable and stationary phase jump modulation devices. The connection is particularly suitable for simple modems with transmission in the acoustic frequency band, for example over telephone lines or radiotelephone connections. The wiring enables maximum use of integrated circuits.

In the known and used modulators for phase jump modulation, the modulated signal is obtained by the classical method. The carrier harmonic signal from the oscillator is converted to two suitably phase shifted voltages (phase shift is usually π) and keyed respectively. switched by electronic switches. The electronic switches are controlled by logic circuits which suitably encode the incoming data. For proper operation of the system it is necessary that the carrier of the carrier signal is synchronized with the data signal. Most of the circuits are analogue and consist of discrete components. In order to achieve the correct function, the analog part of the circuits must be set individually during production. Although it is possible to replace most of the discrete components with integrated circuits in this system, their implementation is generally not economically advantageous. Neither monolithic or hybrid integration of the whole modulator is economically advantageous.

These disadvantages are overcome by the connection of the data modulator according to the invention. Its essence is that it contains a clock pulse generator, to whose first output is connected the first binary divider. A second binary divider, the output of which is connected to the clock memory input, is connected to the second, anti-phase output of the clock pulse generator. Its output is connected via the third binary divider to the first input of the non-equivalence circuit, the second input of which is connected to the output of the first binary divider. The non-equivalence output is connected to the output terminal via a filter. The resulting signal is obtained by the synthesis of rectangular voltage waveforms in a simple set of logic circuits and adjusted to the desired waveform by limiting the frequency spectrum by a simple filter at the output of the modulator. The synchronization of the carrier and data signals is ensured by the fact that the carrier

Claims (2)

Subject Connection of a data transmission modulator, characterized in that it comprises a clock pulse generator (1), the first output of which is connected to the first binary divider (2) and to the second counter-phase output of the clock pulse generator (1) is connected to the second binary divider (3) , whose output is connected at the same time serves as a source of clock pulses for data retrieval from memory. Rectangular voltage waveform synthesis is provided by three binary frequency dividers and a non-equivalence circuit. In the simplest case, a simple RC low-pass filter is sufficient to limit the frequency spectrum at the output. The consistent introduction of logic circuits into the modulator provides considerable economic benefits. The circuitry of the invention does not require adjusting elements and allows complete integration into a single chip of the monolithic circuit. The waveform of the modulated signal at the output of the modulator according to the invention differs somewhat from the waveform of conventional modulators, after passing both signals through the same transmission path the differences between them completely disappear and are treated in the same way by the demodulator. The invention is illustrated in more detail by way of example with reference to the accompanying drawing. The connection of the modulator for data transmission consists of a 1-hour pulse generator, to whose first output a first binary divider is connected 2. The second binary divider 3 is connected to the second counter-phase output of the clock pulse generator 1, the output of which is connected to the clock input of the memory 4. The memory output 4 is connected via the third binary divider 5 to the first with the output of the first binary divider 2. The output of the non-equalized circuit 6 is connected to the output terminal via a filter 7. The output of the second binary divider 3 serves as a source of clock pulses to provide the data from the memory 4. The data signal from the memory output 4 is applied to the input of the third binary divider S and from its output to one of the inputs of the non-equalized circuit 6. A signal from the output of the first binary divider is applied to the second input of the nonequivalent circuit B 2. The signal from the non-equivalence circuit output B is then shaped by a low-pass or band-pass filter 7. The connection was realized with common TTL circuits and CMOS logic circuits. The realization fulfilled all expectations, ie reliable and reproducible operation without the need for individual adjustment of partial circuits. INVENTION for a clock input of memory (4), the output of which is connected via a third binary divider (5) to a first input of the non-equivalence circuit (6), a second input of which is connected to the output of the first binary divider (2), it is connected to the output terminal via a filter (7).