EP0870395A2 - Method and arrangement for monitoring of metering pulses in a telephone system - Google Patents

Abstract

The invention relates to a method and arrangement for monitoring of metering pulses in a telephone system which are transmitted as cycles, occurring in pulses, of an oscillating frequency which is above the voice frequency band. To achieve digital evaluation of the metering pulses while maintaining a low level of outlay for analogue/ digital conversion, metering pulses (6) modified by modulation with rectangular pulses are produced with a low frequency spectrum components in the voice band, thus enabling conversion using economical coders (7).

Description

Method and arrangement for recognizing charge pulses in a telephone system

State of the art

The invention is based on the genus as stated in the independent claims.

Charge pulses are pulse-shaped (sine) oscillation trains with an oscillation frequency (fG) of 12 kHz or 16 kHz. These are usually selected with a bandpass filter and then detected (Martin Hebel, handbook for self-dialing long-distance traffic, 1962, p. 146).

To ensure the selectivity required in some countries, high-order filters must be used or the evaluation must be carried out using the frequency counting method. Commercially available ICs are commonly used today. Advantages of the invention

The subject of the application with the features of the independent claims has the following advantages:

Provided that the charge impulses are modulated with a suitable modulation method in such a way that there is a spectral component at a frequency, in particular in the band range from 300 Hz to 3400 Hz, the modified charge pulse can be evaluated with the aid of a digital signal processor which uses a CoDec receives the signal sampled with only 8 kHz (the original charge pulse with the oscillation frequency fG requires a sampling rate> 32 kHz for digital evaluation, which requires a fast and expensive AD converter).

The charge pulse of, for example, fG = 16 kHz is multiplied by a square wave whose frequency (the fundamental wave) z. B. corresponds to 14 kHz (fR). This square wave signal for modulation is easy to generate. The spectral distribution of a periodic square wave signal can be calculated using the Fourier series. The fundamental wave of the square-wave signal, modulated with the charge pulse, supplies the spectral component fA to be evaluated, where fA is the difference between fG and fR (e.g. 2 kHz). The effective value of the modified charge pulse is proportional to the effective value of the charge pulse.

Other advantages of this solution:

- There are two hardware circuit versions (for 12 or 16 kHz) sufficient for most countries.

- Simple hardware (standard operational amplifiers are inexpensive and available).

Simpler band filter. - Evaluation of frequency selectivity, level and

Pulse times possible via software in the digital signal processor (with known advantages).

- The same square-wave signal of 14 kHz can be used for 12 kHz and 16 kHz charge pulses in order to achieve a spectral component of fA = 2 kHz in the spectrum of the modified charge pulse.

In the solution described so far, it is necessary to use analog low-pass or band-pass filters to suppress image frequencies that are undesirable

Addressing the arrangement could lead to the detection of charge pulses (example: oscillation frequency of the oscillation trains of the charge pulses 16 kHz, modulation frequency 18 kHz. With this combination, the resulting frequency to be evaluated by a digital signal processor is 2 kHz. If an interference frequency of 20 kHz now occurs, then one of the modulation products also has a frequency of 2 kHz). The low-pass or band-pass filters required to suppress such disruptive modulation products must have relatively steep flanks and therefore require a certain amount of components (amplifiers, closely tolerated resistors and capacitors).

With a preferred embodiment of the invention, it has been possible to hide the image frequencies in a different way and thus to save the filters. In doing so the oscillation trains of the charge pulses preferably modulated with a square wave signal. However, the frequency of this modulation signal is not constant, but preferably changes periodically between two values, one of which is below the oscillation frequency of the

Vibration trains and the other by the same amount above the vibration frequency of the vibration trains of the charge pulses (example: vibration frequency of the vibration trains of the charge pulses = 16 kHz, first modulation frequency = 14 kHz, second modulation frequency = 18 kHz). The times between two switching of the modulation frequencies must be longer than the evaluation times in the digital signal processor of e.g. 15 milliseconds.

If one looks at the modulation products at an oscillation frequency that corresponds to that of the oscillation trains of the charge pulses, the same component of 2 kHz results at each of the two modulation frequencies, which is therefore constantly applied to the digital signal processor and leads to detection.

When an interference frequency is applied (e.g. 20 kHz, see above), the component of 2 kHz only appears in connection with one of the two modulation frequencies. The digital one

The signal processor therefore receives a 2 kHz signal for 15 milliseconds and then no signal for 15 milliseconds. The digital signal processor must reject such a pattern.

The implementation of the frequency switching is relatively simple and does not need to bring any additional effort when generating the modulation frequencies in a PAL (Programmable Array Logic), which only has to be programmed differently.

drawings

Embodiments of the invention are shown in the drawings and explained in more detail in the following description. It is shown in FIG. 1: a block diagram of an arrangement according to the invention for the detection of charge pulses, FIG. 2: timing diagrams and FIG. 3: a block diagram of a further arrangement according to the invention for the detection of charge pulses.

Description of the exemplary embodiment according to FIG. 1: Structure of the preferred exemplary embodiment:

The arrangement 1 shown as a block diagram for the detection of charge pulses is connected with its input 1 to the a / b wires of an outside line of a telephone system. In this way, the charge pulses are fed to a differential amplifier 2, from where they reach a bandpass filter 3 after amplification. Its output is connected on the one hand directly to an input of a modulator (MUX) 5, while on the other hand a second input receives the charge pulses from the bandpass 3 inverted via an inverter 4. The modulator 5 has another one for the modulation signal in the form of a square-wave signal R.

Entrance. Modified charge pulses 6 leave the output of the modulator 5, which arrive at a coder (CoDec) 7 to form a digitally sampled signal which is fed to a digital signal processor (DSP) 8, which is connected via a microprocessor interface (μP interface) 9 a microprocessor works together.

Function of the preferred exemplary embodiment:

The process of recognizing a charge pulse is as follows:

1. Tapping the signal on the a / b wire before bandpass 3 (fee cut filter).

2. Formation of a differential voltage with the differential amplifier 2.

3. Filtering with the bandpass filter 3 for the oscillation frequency of the charge pulses. The bandpass does not need to ensure frequency selectivity, but must suppress frequencies that lead to the same spectral component as the fee impulses. For example, fR - fG = fA if fG <fR.

4. Formation of an inverted signal with the inverter

5. An analog switch in modulator 5 switches (controlled by the square-wave signal) between the original and the inverted signal (corresponds to multiplication with a square-wave signal without a DC component). 6. The output signal is now ready for evaluation.

7. It is digitized via CoDec 7 and fed to a digital signal processor (DSP) 8.

8. The DSP first performs bandpass filtering. The required frequency selectivity (± 500 Hz in some countries) is easy to implement. The evaluation is carried out by subsequent amplitude and time evaluation, as is known, for example, from the audio tone detectors of the Integral3 series from Bosch Telecom GmbH.

Under unfavorable conditions, there may be disturbances in the detection of charge impulses. For example, if the oscillation frequency of the oscillation trains of charge pulses is 16 kHz and the modulation frequency is 18 kHz, the resulting frequency to be evaluated by the digital signal processor is 2 kHz. With an interference frequency of 20 kHz on the a / b wires, however, one of the modulation products generated in the modulator 5 is also 2 kHz. A further development of the invention provides a remedy here, for which an exemplary embodiment is shown in FIG. Figure 2 explains the mode of operation.

Figure 2 shows timing diagrams during a

Period of 60 milliseconds. In FIG. 2A, the oscillation frequency f _{G of} an oscillation train of a charge pulse is present in this period. The modulation frequency f _moc ι (frequency f _{R of} the square-wave signal R in Figure 3) changes in time intervals of 15 milliseconds between 14 kHz and 18 kHz. Incidentally, FIG. 3 corresponds - in so far as the reference symbols match - in principle to Figure 1. The difference frequency f _A , which leaves the modulator 5, is 2 kHz in the entire period shown in Figure 2A.

FIG. 2B shows the same conditions for the presence of an interference frequency f _s of 20 kHz on the a / b wires. This time the difference frequency f _{A changes} between 6 kHz and 2 kHz. In the desired manner, this change does not lead to the detection of a charge pulse.

Figure 3 is compared to Figure 1 supplemented by the necessary means for generating the change in the modulation frequency f _m od ⁼ ^ R- For this purpose, a frequency counter F is provided, which provides the changing modulation frequencies fl and f2, respectively, by a switch S in time from 15 milliseconds can be switched through to modulator 5 alternately. With an oscillation frequency f _G of 16 kHz, fl = 14 kHz and f2 = 18 kHz. Via a switch input U, the frequency divider F can also be switched to conditions for an oscillation frequency f _G of 12 kHz; the frequencies fl and f2, which alternately the

Forming the modulation frequency is then, for example, 10 or 14 kHz.

Claims

Expectations

1. A method for detecting charge pulses in a telephone system, which are transmitted as pulsating oscillation trains of an oscillation frequency which is above the voice frequency band, characterized in that the oscillation trains are modulated so that modified charge pulses (6) with a spectral component result is below the oscillation frequency of the oscillation trains.

2. The method according to claim 1, characterized in that the oscillation trains are modulated so that modified charge pulses (6) result with a spectral component that can be digitally sampled by means which are identical to the means for sampling the speech signals within the telephone system are provided.

3. The method according to claim 1 or 2, characterized in that the oscillation trains are modulated so that modified fee impulses (6) result with a spectral component within the voice frequency band.

4. The method according to any one of the preceding claims, characterized in that the vibration trains are modulated with rectangular pulses.

5. The method according to any one of the preceding claims, characterized in that the evaluation of the modified charge pulses (6) after digital sampling with the aid of a digital signal processor (8).

6. The method according to any one of the preceding claims, characterized in that a modulation oscillation is used for the modulation, which has a modulation frequency which changes between two values, one of which is about the frequency value of said spectral component below and the other about the same frequency value above that Vibration frequency of the vibration trains is.

7. Arrangement for the detection of charge pulses in a telephone system, which are transmitted as pulsating oscillation trains of an oscillation frequency which is above the voice frequency band, characterized in that in the signal flow direction behind a bandpass filter (3) which is matched to the oscillation frequency of the oscillation trains Modulator (5) follows, which is followed by a digital encoder (7), followed by a signal processor (8), and which delivers modified charge pulses (6) with a spectral component which is below the oscillation frequency of the oscillation trains.

8. Arrangement according to claim 7, characterized in that the encoder (7) is provided for a sampling rate which is below twice the oscillation frequency of the oscillation trains.

9. Arrangement according to claim 8, characterized in that the encoder (7) is provided for a sampling rate which corresponds to the sampling rate for the voice signals in the telephone system.

10. The arrangement according to claim 9, characterized in that the encoder (7) is identical to an encoder which is provided for the voice signals in the telephone system.

11. Arrangement according to one of claims 7 to 10, characterized in that the modulator (5) is fed with a square wave signal as a modulation signal.

12. Arrangement according to one of claims 7 to 11, characterized in that the modulator (5) has a switch which, controlled by the square wave signal, switches back and forth between the oscillation train and the inverted oscillation train.

13. Arrangement according to one of claims 7 to 11, characterized in that the modulator is assigned a vibration generator for the modulation vibration, which provides a modulation frequency (f _{moc |} ) which changes between two values (fl, f2), one of which around about the frequency value of said spectral component is below and the other is about the same frequency value above the oscillation frequency (f _G ) of the oscillation trains.