CH666774A5 - METHOD AND CIRCUIT ARRANGEMENT FOR ADJUSTING THE NEUTRAL POSITION OF A DEMODULATOR. - Google Patents

Description

DESCRIPTION The present invention relates to a method for balancing the neutral position of a demodulator, which is arranged together with a microprocessor in a data transmission device, and to a circuit arrangement for carrying out the method.

In general, the invention relates to data transmission by means of analog transmission methods. In particular, it relates to the news area. It should be irrelevant whether the data is transmitted wirelessly or via metallic conductors or via optical fibers. In known technology, data transmission devices are used for this purpose, which convert an incoming digital data stream into an analog data stream, which is converted back into a digital data stream after the transmission path has been covered.

So-called "modems" consisting of modulator and demodulator are used for converting the data streams. These are modules which convert digital signals into analog signals and vice versa, for example by frequency shift keying or phase shift keying. Such modems are used, for example, in telephone traffic and in screen test devices. They are usually coupled to microprocessors. In order for the data to be transmitted properly and in particular for the recovery of the digital data, the demodulator used in the modem must be able to recognize the incoming analog signal without any problems, for which limits are set. If a binary code is used for the transmission, then the demodulator, for example, must be able to correctly recognize two states. In the case of frequency shift keying, these are, for example, the two characteristic frequencies which are above or below a limit frequency predetermined for the demodulator.

In order that the demodulator can fulfill these tasks and that the data transmission device can operate properly, it must be adjusted to achieve a neutral position. The time and manpower required for this is high in the procedure known today because a matching element is used for the matching, a measuring device has to be read and at least one resistor has to be soldered in. After adjustment, the neutral position of the demodulator is set once and for all, and it is operated with this setting over its entire service life. Aging processes and other influences are no longer taken into account.

The invention has for its object to provide a method and a circuit arrangement with which the adjustment of the neutral position of a demodulator can be achieved in a simpler manner.

The method according to the invention corresponds to the characterizing features in patent claim 1.

This method offers the advantage that the demodulators used in a data transmission device no longer have to be adjusted manually. The time and personnel expenditure previously required for the adjustment is no longer applicable. The adjustment of the demodulators is now carried out in a test process that takes about 0.5 to 1.0 s after switching on the supply voltage of a data transmission link, but before the actual operating phase. In the case of a dedicated line, the “operating phase” is to be understood to mean the data transmission itself, while without a dedicated line it means the process of setting up the transmission path with subsequent data transmission.

It is particularly advantageous that the adjustment process can be carried out every time the supply voltage is switched on, so that the adjustment of the neutral position of the demodulators is always carried out anew. Aging influences and other influences are thereby taken into account constantly.

The transmission data generated for the adjustment of a demodulator can be generated by the microprocessor, which is present in the same device as the demodulator to be adjusted. However, it is also possible to generate the transmission data at the far end of the data transmission link and to route it to the demodulator via a path of the link.

An exemplary embodiment of the invention is described below with reference to a circuit diagram shown in a drawing figure.

A data transmission device [DÜE] 1 is indicated schematically by the dash-dotted line. This data transmission device comprises a microprocessor 2, a modulator 3 and a demodulator 4. It is supplied from a current source indicated by the arrow 5. Modular

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gate 3 and demodulator 4 can be combined to form a dashed-line modem 13. Between the microprocessor 2 and the demodulator 4, a simply constructed integrator 6 is also connected, which consists, for example, of an RC element.

The method according to the invention works, for example, as follows:

After switching on the supply voltage, the data transmission device 1 is initially separated from the data transmission path by a signal from the microprocessor 2. For this purpose, the switch 7 is actuated, which is brought into its position shown in broken lines, in which it connects the modulator 3 to the demodulator 4. As shown, this connection can be made directly or via an attenuator. The data transmission path is indicated by a transmission path 8 and a reception path 9, which are not connected to the data transmission device 1 during the adjustment process. Both paths can be carried out wirelessly or they can consist of metallic conductors or optical fibers.

When the changeover switch 7 is brought into its dashed position, the microprocessor 2 sends transmission data generated by it with a predetermined bit pattern via the path 10 to the modulator 3, which converts the digital data into analog data. The analog data arrive at the demodulator 4 and are returned to the microprocessor 2 via the path 11 as recovered digital reception data. The microprocessor 2 now compares the bit patterns of send and receive data. In the event of a deviation, a compensation signal is sent to the demodulator 4 via the path 12, which is converted into a DC voltage in the integrator 6, for example. The adjustment process that takes place takes approximately

0.5 to 1.0 s. After adjustment, the changeover switch 7 is brought back into its position shown in the drawing, in which the transmission paths 8 and 9 are connected to the data transmission device 1. The actual operating phase of the data transmission device 1 can now begin.

For the alignment process, the microprocessor 2 preferably generates a bit pattern with the pulse duty factor 1: 1 for the transmission data at a corresponding transmission rate. A pulse-width-modulated signal, which adjusts a DC voltage on the demodulator 4 after integration in the simple integrator 6, can preferably be used as the compensation signal between the microprocessor 2 and the demodulator 4. This adjustment ensures that the bit patterns of send data and 15 receive data are the same. The demodulator 4 is adjusted. The pulse ratio used for the adjustment of the demodulator 4 is known to the microprocessor 2. It is stored as a parameter in the memory of the microprocessor 2 and used for the further operation of the data transmission link.

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In principle, the same process takes place when the send data is generated at the far end of the data transmission path. It is then only necessary that the bit pattern of this transmission data is known to the comparative microprocessor 2.

For the sake of completeness, it should be pointed out that the adjustment process according to the invention can in principle be carried out after the supply voltage has been switched on. With short intervals between switching the supply voltage off and on again, the adjustment is not necessary every 30 times. If the supply voltage is present for a very long time, the adjustment can also be carried out in between, for example during transmission breaks.

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Claims (10)

666 774 1. A method for comparing the neutral position of a demodulator (4), which is arranged together with a microprocessor (2) in a data transmission device (1), characterized in that, before the actual operating phase, digital transmit data with a predetermined bit pattern is first generated and in one The modulator (3) is converted into analog data so that the analog data are then fed to the demodulator (4), and then the digital reception data emerging from the demodulator (4) are fed to the microprocessor (2) and compared by the latter with the transmission data, and that in the event of a discrepancy between the bit patterns of transmit data and receive data, the demodulator (4) is adjusted by the microprocessor (2) in the compensation sense. 2. The method according to claim 1, characterized in that the digital transmission data from the microprocessor (2) located in the data transmission device (1) are generated. 2nd PATENT CLAIMS 3. The method according to claim 1 or 2, characterized in that the data transmission path is decoupled from the data transmission device (1) during the adjustment process. 4. The method according to any one of claims 1 to 3, characterized in that the microprocessor (2) generates a bit pattern with the pulse duty factor 1: 1 as transmission data. 5. The method according to claim 1, characterized in that the digital transmission data is generated at the far end of the data transmission path, converted into analog data by the modulator located there and is guided over a path of the data transmission path to the demodulator (4). 6. The method according to any one of claims 1 to 5, characterized in that the microprocessor (2) for adjusting the demodulator (4) generates a pulse-width-modulated adjustment signal, by means of which a DC voltage applied to the demodulator (4) is adjusted after integration. 7. The method according to any one of claims 1 to 6, characterized in that the adjustment signal is stored in the memory of the microprocessor (2) and used for the further operation of the data transmission link. 8. Circuit arrangement for carrying out the method according to claim 1, characterized by a data transmission device (1) in which a demodulator (4), a microprocessor (2), a modulator (3) and a current source (5) is contained. 9. Circuit arrangement according to claim 8, characterized in that an integrator (6) is switched on between the microprocessor (2) and the demodulator (4). 10. Circuit arrangement according to claim 9, characterized in that an RC element is switched on as the integrator (6).