PL181135B1 - Method of and system for modulating signals for data signal transmission purposes - Google Patents

Abstract

1 . A modulation method for transmitting data signals in which the first carrier is modulated using the data signals in a quadrature manner with two sidebands, characterized in that a single sideband signal together with a residual carrier wave is derived from the modulated signal. is converted to the long wave range by mixing with the oscillator frequency and the signal thus processed is emitted 8. A modulation system for transmitting data signals, in which the source of data signals is connected to the input of the RDS encoder, characterized in that the output of the encoder ( 2) of the RDS signal is connected to the first frequency converter consisting of the first mixer (3) and the first oscillator (4), and the output of the first frequency converter is connected to the input of the filter (5) connected at the output to the input a second frequency converter consisting of the second mixer (6) and the second oscillator (7), with the output of the second mixer (6) connected to the input of the long wave amplifier (8). ( 5 1 ) In tel7 H04H 1/00 PL

Description

The present invention relates to a modulation method and a modulation system for transmitting data signals.

Modulation with two sidebands is known in the art.

As a method with a subcarrier wave, double-sideband modulation. It is encountered in various areas of the telecommunication channels, for example in a stereo differential signal, also in the RDS digital data transmission radio signal for carrying program-related supplementary information in ultra short wave broadcasting and in color information in television broadcasting.

It is known from WO 85/05748 to apply PSK phase shift keying modulation of an auxiliary carrier wave to amplitude modulated radio compatible data transmission.

The above-described double-sideband modulations are used especially in telecommunication channels in which the signal bandwidth plays a subordinate role.

The carrier phase needed to demodulate the DSB signal modulated signal is produced, for example, in stereo transmission where a pilot frequency of 19 kHz is transmitted to generate a 38 kHz carrier wave in the FM multiplied signal. Other methods use the Costa loop to recover the carrier wave of two-sidebands with identical sidebands.

In our case, with the intention to transmit the RDS signal (QDSB with two

181 135 identical sidebands) in the long wavelength range, bandwidth restrictions are placed (RDS QDSB = 4.8 kHz).

RDS QdSb radiation with such a bandwidth in the longest and longest wavelength (9 ... 148.5 kHz) would cause interference to adjacent channels of already coordinated data transmitters.

Taking into account this fact and the related disadvantages of DSB transmission, such as double the bandwidth of the radio frequency signal, dividing the transmission energy in equal parts into sidebands, of which only one is needed, double the selectivity bandwidth for the receiver needed increases the probability of signal penetration disruptive.

A general problem in transmitting radio information of an analog or digital type is the required bandwidth of the modulation product. This means that during international or national transmission, one must strive to optimally use the resources of the frequency band suitable for telecommunications.

Single-sideband SSB is used to reduce the bandwidth to digital signals with QAM or PSK modulation. This method, known for example from WO 85/04541, is based on the fact that two sidebands modulations at a dummy radio carrier frequency result in two sidebands containing the same information. However, only one sideband is needed to reproduce this information, which requires special circuits for decoding the received signals with this known method.

The object of the invention is to provide a modulation method for transmitting data signals and a modulation system for transmitting data signals through devices with a greater range, which to a large extent eliminate the above-mentioned disadvantages.

A modulation method for transmitting data signals, in which a first carrier is modulated by a quadrature two sideband method with data signals, characterized in that a single sideband signal is derived from the modulated signal along with a residual carrier wave, which is then converted to long wavelength range by mixing with the oscillator frequency and the signal thus processed is emitted.

Preferably, the single sideband signal along with a residual carrier wave is obtained by a filtering method.

Preferably, the single sideband signal along with a residual carrier wave is obtained by the phase method.

Preferably, the single sideband signal along with a residual carrier wave is obtained by synthetic generation.

Preferably, the modulated signal is obtained by means of an RDS signal encoder.

Preferably, the single sideband signal is produced as a lower sideband signal.

Preferably, the single sideband signal is produced as an upper sideband signal.

A modulation system for transmitting data signals, wherein the source of the data signals is connected to the input of the RDS encoder, characterized in that the output of the RDS encoder is connected to a first frequency converter consisting of a first mixer and a first oscillator, and the output of the first frequency converter is connected to with an input of a filter connected at the output to the input of a second frequency converter consisting of a second mixer and a second oscillator, the output of the second mixer being connected to the input of a long wave amplifier.

An advantage of the invention is that modulation with one SSB sideband known in analog modulation is used in digital modulation with two sidebands (DSB = 2PSK). A typical representative of the application of DSB double-sideband modulation, more specifically QDSB quadrature double-side modulation, is the RDS radio data signal.

The invention also has the advantage of significantly improving the efficiency of the transmitting device, whereby energy costs and costs can be reduced with the same range

181 135 exploitation. The reduction of the bandwidth allows a lower selectivity bandwidth at the receiving end and therefore reduces the likelihood of the ingress of interfering signals.

The modulation method and modulation system for transmitting data signals according to the invention can be implemented quickly and cheaply, are based on known integrated circuits and allow their immediate use in terminal devices.

The subject of the invention is shown in the embodiment in the drawing, where in Fig. 1 there is shown a diagram illustrating RDS modulation with one SSB sideband, in Fig. 2 is a diagram of a modulation circuit for transmitting data signals, and in Fig. 3 is a diagram of a circuit of a data signal receiver. transmitted using the modulation according to the invention.

In the description of the invention and in the drawings, abbreviations have been used with the following meanings:

ARI - radio information for drivers

RDS - radio digital data transmission system

SSB - one sideband

DSB - two sidebands

QDSB - quadrature modulation with two sidebands

USB - upper sideband

LSB - lower sideband

PSK - keyed phase shift

ZF - Intermediate frequency

RF - radio frequency

The difficulties with transmitting the RDS signal on long wavelengths were overcome by using the SSB method known from the analogue transmission technique for QDSB modulation in the rDs system. Unlike analog modulation with SSB, in the case of RDS, a carrier wave that is correct for frequency and phase can be used for demodulation.

Fig. 1 shows an RDS signal with LSB and USB sidebands. The carrier wave, having a frequency of Ω0, which in this embodiment is 57 kHz, is an unmodulated ARI carrier wave known from an ARI system. It is quadrature with respect to the RDS phase and can therefore be used for QDSB sideband demodulation in the RDS system.

Figure 2 shows an RDS QDSB processing circuitry for use on long wavelength. As data source 1, an RDS encoder 2 is used which performs QDSB modulation with or without a carrier frequency.

Filtering is used to produce the USB upper sideband at a carrier frequency (covered by the dashed line in FIG. 1). This means that in the second step the frequency of the QDSB signal in the RDS system (57 kHz) is converted to the bandwidth Ωο - Ωο + ωο (2.4 kHz) of the SSB filter. On the other hand, the first frequency conversion takes place in a first frequency converter consisting of a first mixer 3 and a first oscillator 4.

There is thus, at the output of the filter 5, depending on the selected frequency of the first oscillator 4 of the first frequency conversion, a lower sideband LSB + a carrier wave or an upper sideband USB + a carrier wave at an intermediate frequency position. The second frequency conversion takes place in a second frequency converter consisting of a second mixer 6 and a second oscillator 7 and serves to transpose the obtained one sideband of the RDS signal with a residual carrier frequency (the carrier wave is reduced to the maximum of the sideband amplitude) to the desired transmission frequency . In the next stage, the signal is amplified to the appropriate power in the amplifier 8 and transmitted. It does not matter how the single-sideband signal is produced with the residual carrier wave by means of a filtering method, phase method or by synthetic generation.

As a residual carrier wave, it is possible to use a carrier wave switched on by the RDS encoder 2.

The use of high-grade modulation types with two sidebands should not be ruled out. The use of these methods is not related to the wavelength range.

In the embodiment shown in Fig. 2, the RDS signal is transmitted on a long wave with a frequency of 123.7 kHz.

181 135

Fig. 3 shows a system for receiving data signals transmitted using the modulation method according to the invention, i.e. signals including a residual carrier wave.

With single-sideband transmission in the RDS system, synchronous demodulation (coherent demodulator with an auxiliary carrier wave of the correct frequency and phase) as well as non-synchronous demodulation (without an auxiliary carrier wave) is possible. When using one of the methods of synchronous demodulation, it is necessary to transfer a residual carrier wave in quadrature to the sideband on the transmitting side. Demodulation is performed by synchronous demodulators, with the transferred residual carrier wave being used for synchronous demodulation. Demodulation therefore occurs directly in the baseband. In the case of asynchronous demodulation, it has to be ensured that at the receiving end the non-existent sideband carrier wave pattern is provided by the demodulator. Moreover, it is possible to analyze the demodulation of a signal by having its typical frequency components in the spectrum in the form of "0" or "1", and on this basis to generate a data stream in which the sideband is demodulated asynchronously and finally demodulated by analyzing the frequency components in modulation product spectrum. This means that in demodulation, one is not associated with the newly developed integrated circuit, since the demodulation product in any case is immediately further processed by commercially available circuits.

A known wideband receiver with a synchronous demodulator is used to receive an RDS single-sideband signal without a residual carrier wave. The further processing of the RDS baseband (two-phase signal) poses no technical problems. The use of this method is not related to the wavelength range.

The circuit shown in Fig. 3 comprises a receiving antenna 13, an input amplifier 14, an oscillator 15, a mixer 16, a bandpass filter 17 and a known RDS demodulator 18. From the antenna 13, high-frequency signals are fed to the input amplifier 14. Oscillator 15 produces the frequency fe + fzF, where fe is the frequency of the residual carrier wave included in the high frequency signal and fzF is the intermediate frequency and is 57 kHz. The high-frequency signal amplified in amplifier 14 is then converted in mixer 16 to an intermediate frequency range and passes through a 2.4 kHz bandwidth filter 17 covering a frequency of 57 kHz. Connected thereto is an RDS demodulator 18 which has one output 19 for the timing signal and one output 20 for the data signal. These signals can be decoded according to the rules set for RDS and then fed into the display. In one embodiment, the RDS demodulator 18 is a synchronous demodulator using the residual carrier wave. According to another embodiment, the RDS demodulator 18 is an asynchronous demodulator specifically employing spectrum component analysis of the modulation product.

181 135

RDS-QDSB

RDS- modulated ZF- position RF- 57-kHz radio signal- carrier _. _

Fig.2

Fig.3

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Claims (8)

Patent claims A modulation method for transmitting data signals, wherein a first carrier is modulated by a quadrature two sideband method by means of data signals, characterized in that a single sideband signal is derived from the modulated signal together with a residual carrier wave, which is then processed to the long wavelength range by mixing with the oscillator frequency and the signal thus processed is emitted. 2. The method according to p. The method of claim 1, wherein the single sideband signal together with a residual carrier wave is obtained by a filtering method. 3. The method according to p. The method of claim 1, wherein the single sideband signal together with a residual carrier wave are obtained by the phase method. 4. The method according to p. The method of claim 1, wherein the single sideband signal together with a residual carrier wave is obtained by synthetic generation. 5. The method according to p. The method of claim 1, characterized in that the modulated signal is obtained by means of an RDS signal encoder (2). 6. The method according to p. The method of claim 2 or 5, characterized in that the single sideband signal is produced as a lower sideband signal. 7. The method according to p. The method of claim 2 or 5, characterized in that the single sideband signal is produced as an upper sideband signal. 8. A modulation system for transmitting data signals, wherein the source of the data signals is connected to an input of an RDS encoder, characterized in that the output of the RDS signal encoder (2) is connected to a first frequency converter consisting of a first mixer (3) and a first oscillator (4), and the output of the first frequency converter is connected to the input of the filter (5) connected at the output to the input of the second frequency converter, consisting of a second mixer (6) and a second oscillator (7), the output of the second mixer (6) being connected to with long wave amplifier input (8).