WO1999066687A1 - Differential coherent demodulation of dbpsk signals - Google Patents

Abstract

According to the invention, a demodulator is provided for demodulating a digitally modulated high frequency signal. Said demodulator has a mixer (2) to which a signal for demodulating S1 and a second signal S2 from a local oscillator (3) are conveyed. A divider (19) divides the output signal of the mixer (2) into a first and a second branch and a delay unit (6) delays the two branches by a predetermined phase (for example, 90°) in relation to each other. An evaluation unit (7) determines the position of the signal vector corresponding to a modulation based on the delayed and undelayed branch of the output signal of the mixer (2). The phase of the second signal S2 from the local oscillator (3) is modified by a predetermined value at predetermined intervals. The phase of the second signal from the local oscillator (3) may, for example be modified after each bit received, by a value corresponding to the rotation of the signal vector due to the modulation.

Description

 description

DIFFERENTIAL OHARENT DEMODULATION OF DBPSK SIGNALS

The present invention relates to a demodulator, a method for demodulating a digitally modulated RF signal and a mobile radio device having such a demodulator.

The present invention relates generally to the field of modulating digitally modulated RF signals. An example of such a modulation is, for example, phase shift keying (PSK, phase shift keymg, in which the information to be transmitted is placed on the phase change of a high-frequency carrier voltage. In PSK with reference phase, the phase change relates to the non-modulated carrier voltage. PSK, the phase change relates to the state preceding the change, and this phase shift keying is based on the phase difference between the successive states

Phase state of the bit compared with the state αes - ^τ or received bits. On the transmission side, a pulse is scanned, the frequency of which is as large as the transmission rate

from.

To demodulate, for example, a two-phase shift keying (2-PSK), the receiver demodulates, for example, using a multiplier or ring modulator. This can be controlled with a square-wave AC voltage which is as large in frequency as the carrier frequency of the transmitter. The multiplier or ring modulator of the receiver is controlled synchronously with the multiplier or ring modulator.

The so-called limiting homodyne receivers have the disadvantage that they are not suitable for systems with high data rates, since the rotation of the signal vector according to the modulation in the complex signal level is not reliably is sufficient to ensure that the axes are exceeded and thus the signal is clearly recorded.

A solution to remedy this problem is the so-called multi-axis demodulator, which is shown in FIG. 2. In a multi-axis demodulator, the I (in-phase component) and Q (quadrature-phase component) of the demodulated signal are generated from the signals by linking additional axes, so that a rotation of the signal vector can be detected in accordance with a modulation. As can be seen in FIG. 2, an received RF signal to be demodulated is divided into two branches by an antenna 1, one branch being delayed by 90 ° with respect to the other (6). The I component and the Q component of the modulated signal are thus provided in a known manner. Now there are links (8, 9, 10) of the I and Q components in order to create several axes. The output signals of the link (8, 9, 10) are mixed (11, 12, 13) with an output signal of a local oscillator (14). Then the downmixed signals, i.e. the output signals of the mixers 11, 12, 13 limiters (limiters) 15, 16, 17 are supplied, and the output signals of the limiters 15, 16, 17 are each fed to an evaluation unit 18 for detecting the rotation of the signal vector in accordance with the modulation. As can be seen from FIG. 2, a multi-axis demodulator has the disadvantage that it requires a lot of effort to implement it, since, for example, a corresponding limiter stage and a mixer are required for each axis.

It is therefore the object of the present invention to provide a de odulation technique in which the deodulation accuracy is comparable to that of a multi-axis demodulator and at the same time the implementation effort can be reduced.

The basic idea according to the present invention to achieve the above object is to do so during the Demodulation to adjust by the phase of a local oscillator.

More precisely, the above-mentioned object is achieved by the features of the independent claims.

The dependent claims further develop the central idea of the invention in a particularly advantageous manner.

According to the invention, a demodulator for demodulating digital modulated RF signals is therefore provided. The demodulator has a mixer to which a signal to be demodulated and a second signal from a local oscillator are supplied. A divider divides the output signal of the mixer into a first and a second branch. A delay unit delays one of the first and second branches by a predetermined phase, for example by 90 °. An evaluation unit then determines the position of a signal vector which corresponds to a modulation on the basis of the delayed and the non-delayed branch of the output signal of the mixer. The phase of the second signal from the local oscillator is changed according to the invention in predetermined sections by a predetermined value.

The phase of the second signal from the local oscillator can be changed, for example, after each bit received.

The phase can be changed by a value that corresponds to the rotation of the signal vector due to a modulation. The evaluation unit can determine in which quadrant the signal vector is located.

The demodulation can be carried out in that the evaluation unit determines whether the signal vector is in the same quadrant as in the immediately preceding sampling. According to the invention, a method for demodulating a digitally modulated RF signal is also provided. A signal to be demodulated and a second signal from a local oscillator are fed to a mixer. The mixer output signal is divided into a first and a second branch. The two branches are delayed against one another by a predetermined phase. The position of a signal vector which corresponds to a modulation is then determined on the basis of the branches of the output signal of the mixer which are delayed relative to one another. The phase of the second signal from the local oscillator can be changed by a predetermined value at predetermined intervals.

According to the present invention, a mobile radio device is also provided which has a demodulator with the features mentioned above.

The present invention will now be explained in more detail with reference to an embodiment. For further clarification of features and advantages of the invention, reference is made to the accompanying figures of the drawings, in which:

1 shows an embodiment of a demodulator according to the present invention, and

Fig. 2 shows a demodulator according to the prior art.

An embodiment of a demodulator according to the present invention is shown in FIG. 1. A first signal S1 from an antenna 1 is fed to a mixer 2. The mixer 2 is also fed a second signal S2 from a local oscillator (synthesizer) 3. The phase of the second signal S2, which is output by the local oscillator 3, can be changed by a phase control unit 4 in adjustable increments by a selectable value. The output signal of mixer 2 becomes a limiter (Limiter) 5 fed. A divider 19 divides the output signal of the limiter (limiter 5) into two branches, one branch Q being delayed by 90 ° with respect to the other branch I by means of a delay unit 6. An evaluation unit 7 then determines the position of a signal vector that represents a modulation, starting from the two supplied signal components I, Q. The phase control unit 4 is connected to the evaluation unit 7 in order to transmit the information to the latter, such as, in particular, in which Direction (sign of the phase change) the phase of the output signal S2 is changed.

The output signal S2 of the local oscillator 3, which is used for mixing 2 the signal S1 to be received, can be adjusted in phase, for example, after each received bit (sampling). The signals I and Q then form a common coordinate system in which the useful signal to be received lies and rotates, the direction of rotation of the coordinate system according to the detected signals I and Q indicating whether a "1" or a "0" is transmitted. By adjusting the phase of the output signal S2 of the local oscillator 3, the coordinate system, as it were, which is formed by the axes of the signals I and Q, is continuously updated. Due to this bit-wise tracking of the coordinate system, it is no longer necessary in the present invention to form several axes by linking the I and Q signals in order to detect the rotation of the signal vector.

The adjustment of the phase of the output signal S2 of the local oscillator 3 corresponds to a rotation in the complex I, Q plane through the coordinate system spanned by the I and Q signals. The angle by which the phase of the output signal S2 of the local oscillator 3 is adjusted after each bit received is selected so that it corresponds to the rotation of the signal vector due to the modulation, so that the evaluation unit 7 modulates the position of the signal vector onto the modulated one Data can close. The evaluation unit 7, which, so to speak, represents a demodulation unit in itself, then evaluates the position of the signal vector by, for example, using the ratio of the I and Q components to determine which quadrant of the complex I, Q plane the signal vector is located in. If the signal vector is in the same quadrant as in the immediately preceding sampling, the signal vector has rotated in the direction of the coordinate system, ie it has rotated together with the coordinate system. If, however, the signal vector in the current scan is in a different quadrant than in the immediately preceding scan, the signal vector has rotated counter to the rotation of the coordinate system.

It should be noted that the evaluation unit / demodulation unit 7 knows in which direction the coordinate system was rotated, i.e. it is supplied with a signal 20 which indicates the phase adjustment by the phase control unit 4. The modulated data are assigned to a direction of rotation, so that, for example, a rotation of the signal vector in the complex I, Q plane corresponds to "1" and a rotation of the signal vector in the complex I, Q plane to the right corresponds to "0". corresponds.

That is, according to the present invention, instead of defining a multiplicity of new axes, as is the case with the multi-axis demodulator according to the prior art, by means of a targeted phase shift of the output signal S2 of the local oscillator 3, the unit circuit is resolved into many sectors whereby the demodulation accuracy can be kept the same and at the same time the implementation effort can be reduced, since only a limiter stage and a mixer are required.

Claims

claims

1. Demodulator for demodulating a digitally modulated RF signal, comprising - a mixer (2) to which a signal (S1) to be demodulated and a second signal (S2) are supplied by a local oscillator (3),

- a divider (19) which divides the output signal of the mixer (2) into a first and a second branch, - a delay unit (6) which delays one of the first and the second branch by a predetermined phase, and

- An evaluation unit (7) which, based on the delayed and the non-delayed branch of the output signal of the mixer (2), determines the position of a signal vector which corresponds to a modulation, characterized in that the phase of the second signal (S2) from the local oscillator (3) is changed by a predetermined value at predetermined intervals.

2. Demodulator according to claim 1, characterized in that the phase of the second signal (S2) by the local oscillator (3) is changed after each bit received.

3. Demodulator according to one of the preceding claims, characterized in that the phase is changed in each case by a value which corresponds to the rotation of the signal vector due to a modulation.

4. Demodulator according to one of the preceding claims, characterized in that the evaluation unit (7) determines in which quadrant the signal vector is located.

5. Demodulator according to claim 4, characterized in that the evaluation unit (7) determines whether the signal vector is in the same quadrant as in the immediately preceding sampling.

6. A method for demodulating a digitally modulated RF signal, comprising the following steps: - supplying a signal (S1) to be demodulated and a second signal (S2) from a local oscillator (3) to a mixer (2),

- dividing (19) the output signal of the mixer (2) into a first and a second branch, - delaying (6) one of the first and the second branch by a predetermined phase, and

- Determining (7) the position of a signal vector which corresponds to a modulation on the basis of the delayed and the non-delayed branch of the output signal of the mixer (2), characterized in that the phase of the second signal (S2) from the local oscillator (3) is changed at predetermined intervals by a predetermined value.

7. A method for demodulation according to claim 6, characterized in that the phase of the second signal (S2) is changed by the local oscillator (3) after each bit received.

8. A method for demodulation according to one of claims 6 or 7, characterized in that that the phase is changed by a value which corresponds to the rotation of the signal vector due to a modulation.

9. A method for demodulation according to one of claims 6 to 8, characterized in that an evaluation unit (7) determines in which quadrant the signal vector is located.

10. A method for demodulation according to claim 9, characterized in that the evaluation unit (7) determines whether the signal vector is in the same quadrant as in the immediately preceding sampling.

11. Mobile radio device, comprising a demodulator according to one of claims 1 to 5.