DE4214125C1 - Signal level and frequency monitoring for telephone call tone circuit - feeding frequency information for call tone input signal to microprocessor via DC voltage converter providing galvanic separation - Google Patents

Abstract

The monitoring method involves using a threshold comparator for monitoring a level of a call tone input signal (TRES). Its frequency is monitored by extracting frequency information transmitted to an evaluation microprocessor (MP) via a galvanic separation stage. A DC-DC voltage converter (WDL) controlled by a HF clock signal (TS) uses a pulse sequence containing the frequency information. Each of the pulses has a short duration relative to the half wave duration of the call time input signal to provide spaces in the HF clock signal, evaluated on the secondary side of the DC voltage converter to detect the frequency of the call time input signal. ADVANTAGE - Eliminates need for opto-coupler.

Description

Procedure for level and frequency monitoring at the Über Carrying of line-bound signals for signal-dependent processes, in particular ringing input signals for triggering solution of a ringing tone in telephone terminals.

The invention relates to a method for level and Fre frequency monitoring according to the preamble of claim ches 1.

The frequency and level of wired signals need to cover several technical areas from the various reasons are monitored; so z. B. in the Communication technology, where on two-wire lines, so called a / b lines, ringing and voice signals over will wear. In order to transmit the ringing under various response conditions for the ringing calls of the di verse postal companies, it is necessary the level and frequency of one on the two-wire line ringer input si transmitted to a telephone terminal gnals to monitor.

Such a method for level and frequency monitoring chung is sold at the Com continued telephone "IQ-Tel 2" applied. With the applied The process is an optocoupler for the electrically isolated Transmission of the signal needed for the Fre sequence monitoring provided by means of a microprocessor is. Such a comfort phone is republished in the light print "Telekom-Unterrichtsblätter - Die Telekom magazine for education and training - " 45, 8/1992, pages 296-305.

The object of the invention is a method for level and Frequency monitoring in the transmission of cable bundles which signals for signal-dependent processes, in particular Ringer input signals for triggering a ringer in remote speaking devices to modify so that an optocoupler is no longer needed.

This happens in the preamble of the claim 1 defined method according to the invention in the characterizing part of claim 1 specified Activities.

The elimination of the optocoupler means less effort adornment and facilitates the integration of the whole Arrangement.

Advantageous developments of the invention are in the Un specified claims.

An embodiment of the invention is illustrated in FIGS. 1 to 5. Show it:

Fig. 1 is an electronic device for frequency and Pe gelüberwachung of transmitted on a two-wire line signals,

Fig. 2 shows a possible voltage curve of the wire line at the two transmitted signal,

Fig. 3 is a generated from the electronic scanning of the transmitted on the two-wire line signal pulse train having a sample from this resulting in the pulse repetition rate and pulse width,

Fig. 4 shows the voltage curve of an electronically generated from a clock signal for an inductive switching regulator (DC / DC wall-ler) and the pulse train beat signal,

Fig. 5 shows the voltage curve of the potential-free with the transmitted in the inductive switching regulator and rectified on the secondary side of the inductive switching regulator overlay signal.

Fig. 1 shows an electronic arrangement of a telephony terminal 1 , with the frequency and level of a TRS transmitted on a two-wire line a / b monitored tone signals. The monitoring of the signal frequency and the level is necessary because depending on where the telephone device is used, countries have to meet different response conditions, according to which the telephone device transmits audible acoustic signals when transmitting the incoming call signal TRES via a loudspeaker LSP may give up.

The sound at the inputs E1, E2 of the electronic arrangement 1 lying on the two-wire line a / b transmitted sound input signal TRES with an alternating voltage U _{a / b} is first of all via an isolating capacitor C _TR and a resistor R _V , which are connected in series, a bridge rectifier BGR fed. By rectification with the bridge rectifier BGR, both half-waves of the ringing signal TRES are used, on the one hand by buffering them in a buffer capacitor C _P and then transferring them to a transformer TRF of a DC / DC converter WDL and on the other hand being transferred to a comparator KOM. The tone call input signal TRES is recognized in the comparator KOM. For this detection of the incoming call signal TRES, the signal level is compared with a response threshold ASW1, ASW2 ( FIG. 2). With this level monitoring, it is checked whether, due to the response condition to be fulfilled for the telephone device, the incoming signal is sufficient to emit a ring signal via the loudspeaker LSP. If the signal level is too low, no ringing signal may be emitted from the loudspeaker LSP. If, on the other hand, the signal level is greater than the response threshold ASW, then the first prerequisite for the delivery of the ring signal is already fulfilled. In order to also be able to check the second response condition, the frequency of the incoming call signal TRES, frequency detection is carried out in a pulser via PG. For this frequency detection, the tone signal input signal TRES monitored in the comparator KOM is sampled with each polarity change of the tone signal input signal TRES.

This scanning is illustrated in FIG. 2 for a period of, for example, sinusoidal Tonrufeingangssignals TRES. The pulse generator PG evaluates both half-waves within this signal period.

By means of a pulse shaper PF connected downstream of the pulse generator PG, these scans according to FIG. 3 are converted into a pulse sequence IF of pulses I ₁ . . . I _n with a certain pulse width I _BR and a certain pulse frequency I _FR transformed. If the response threshold ASW1, ASW2 is not exceeded or undershot during the scanning according to FIG. 2, then no pulses I ₁ . . . I _n generated according to FIG. 3. The pulse frequency I _FR with which the pulses I ₁ . . . I _n successive in time is determined by the sampling frequency. The pulse width I _BR, however, is determined exclusively by the pulse shaper PF. For the present embodiment, for example. B. a pulse width I _BR with I _BR = 32 × l / f _clock fixed; the pulse width I _BR is f _clock depending thus solely by the clock frequency. The se clock frequency f _clock from a clock generator he TG evidence that the DC / DC converter WDL is connected to the transformer TRF, and a high frequency clock signal TS with this same clock frequency f _clock a to a logic circuit LS (in this case AND gate ) issues. The pulse sequence IF is supplied to the logic circuit LS as a further input variable. In this logic circuit LS, the pulse sequence IF and the clock signal TS are electronically superimposed. This superposition results in a control signal AS at the output of the logic circuit LS, which is shown in FIG. 4.

In the sense of a more compact structure of the telephone 1 , the comparator KOM, the pulse generator PG, the pulse former PF, the clock generator TG and the logic circuit LS are preferably arranged in an integrated circuit IC (integrated circuit). In principle, it is also possible to build the circuit parts mentioned discretely.

The drive signal AS has the pulse frequency I _{FR in} time succession and with the pulse width I _BR blanking gaps AL occurring. This Ansteuerungssi signal AS with the blanking gaps AL is connected to a switching element SE, z. B. placed on the base of a bipolar transistor. The switching element SE forms, together with the transformer TRF, the DC / DC converter WDL. The DC / DC converter WDL is characterized by that when the switching element SE is open, ie when a current (I _CE ≠ 0) flows between the collector and emitter of the bipolar transistor, the energy to be transmitted in the primary winding of the transformer TRF is stored and that when closed Schaltele element SE, ie if no current (I _CE = 0) flows between the emitter and collector of the bipolar transistor, the energy stored in the primary winding of the transformer TRF will pass to the secondary side of the transformer TRF . On the secondary side of the DC / DC converter WDL, the transmitted energy is delivered to an electronic evaluation / control device ASE.

The evaluation / control device ASE contains a detection circuit DS and a rectifier circuit GRS with a downstream microprocessor MP, which are connected in parallel to the secondary side of the DC / DC converter WDL. The rectifier circuit GRS consists of a diode D1 and a parallel circuit connected in series with a smoothing capacitor C _GL and a high-resistance load resistor R _{L1 of} the microprocessor MP. The detection circuit DS consists of a diode D2, which is connected in series with a parallel circuit comprising a detection resistor R _DS , a detection capacitor C _DS and a second very high-resistance load resistor R _L2 (CMOS input with R _L2 → ∞) of the microprocessor MP. The detection circuit DS is dimensioned by appropriate dimensioning of its electronic components so that the blank space AL of the control signal AS transmitted on the secondary side can be detected by the microprocessor MP (detection signal DSI in FIG. 5). Since the time constant τ _DS ≈R _DS × C _DS (R _L2 → ∞) is significantly smaller than the time constant τ _GRS = C _GL × R _L1 (τ _GRS »τ _DS ), the steady state on the smoothing capacitor C _GL supply voltage applied due to the large time constant GRS hardly influenced by the short blanking interval AL be. On the other hand, due to the small time constant DS, a detection AC voltage U _DS (detection signal DSI) applied to the detection capacitor C _DS of the detection circuit DS drops so far that the logic input threshold of the microprocessor MP falls below. In this way, all transmitted blanking gaps AL are recognized and evaluated by the microprocessor MP.

If the evaluated frequency of the ringing input signal TRES meets the predetermined response condition for the telephony terminal 1 , then after the level has already met the required response conditions, the loudspeaker LSP of the telephony device 1 is controlled by an amplifier V from the microprocessor MP and thereby from the loudspeaker LSP issued a ring signal. If the evaluated frequency of the incoming call signal TRES does not meet the required response condition even with an already valid signal level of the incoming call signal TRES, the incoming call signal does not appear.

Claims (4)

1. Method for frequency and level monitoring in the transmission of line-bound signals for signal-dependent processes, in particular ringing call input signals (TRES) for triggering ringing calls in telephony devices ( 1 ),
in which, for level monitoring, the signal (TRES) transmitted on line (a, b) is detected with respect to its level by a threshold value comparison,
in which frequency information is generated for frequency monitoring from the signal (TRES), transmitted in an electrically isolated manner and evaluated in a microprocessor (MP) and
in which use is made in particular of a high-frequency oscillating DC-DC converter (WDL) with electrical isolation, which generates a high-frequency signal from the rectified signal (TRES), which is fed to the microprocessor (MP) after rectification and smoothing,
characterized,
that the DC-DC converter (WDL) is driven with a high-frequency clock signal (TS),
that a pulse sequence (IF) containing the frequency information is generated with pulses (I1... In), the pulse width (I _BR ) of which is small compared to the half-wave duration of the signal (TRES),
that the pulses (I1... In) are provided to form blanking gaps (AL) in the high-frequency clock signal (TS) of the DC voltage converter (WDL) and
that on the secondary side of the DC-DC converter (WDL) the time interval of the blanking intervals (AL) for determining the frequency of the signal (TRES) transmitted on the line (a, b) is used for the signal-dependent processes. 2. The method according to claim 1, characterized ge indicates that the impulses (I1... In) of the Pulse sequence (IF) each time a po is exceeded sitiv threshold (ASW1) or falling below a equally large negative threshold value (ASW2) generated will. 3. Arrangement for performing the method according to one of claims 1 or 2,
with a comparator (KOM) which, based on the threshold value comparison, detects the level of the signal (TRES) transmitted on line (a, b),
with the DC-DC converter (WDL), which is followed by an evaluation / control device (ASE) which has the microprocessor (MP), the feed input of the microprocessor (MP) via a rectifier (D1) with a downstream smoothing element (C _GL , R _L1 ) large time constant is connected to the secondary side of the DC-DC converter (WDL),
characterized,
that the comparator (KOM) is followed by a pulse generator (PG) and a pulse former (PF) for generating the pulse train (IF) with the pulses (I1... In) of a defined duration,
that a logic circuit (LS) for generating a control signal (AS) for a switching element (SE) of the DC converter (WDL) is connected on the input side to the pulse shaper (PF) and a clock generator (TG) for the DC converter (WDL),
that the DC-DC converter (WDL) is connected on the output side to the evaluation / control device (ASE) which has a rectifier (D1) with a downstream smoothing element (R _DS , C _DS ) with a small time constant for the detection of the potential-free transmitted blanking (AL). 4. Arrangement according to claim 3, characterized, that the comparator (KOM), the pulse generator (PG), the pulse form mer (PF), the logic circuit (LS) and the clock generator (TG) are arranged in an integrated circuit (IC).