NL8402260A - Telephone selection tone detector circuit - uses filters and comparator to convert AF tones to signals suitable for microprocessor - Google Patents

Abstract

The input from the telephone line is fed to a first operational amplifier which acts as a first order high pass frequency filter. The filtered signal is then fed to a second operational amplifier which acts as a second order low pass filter, the output of which is fed to an amplitude comparator. The reference voltage fed to the amplifiers and the comparator is produced by a fourth operational amplifier. The comparator output is fed to the control processor which is connected via data and address buses to a memory. The processor checks the period between the rise and fall edges of the signal to determine if the detected pulses are genuine selection signals.

Description

£ - N.0. 32628 l

Dial tone detector.

Applicant mentions as inventors:

Ir. Jacobus Johannes Constant Marie Hoefsloot.

Andrew Vincent Park B.Sc.

The present invention relates to the detection of dial tones in a telephone system, in particular for use in a subscriber set.

There are known per se dial tone detectors which are provided with a series connection of a band filter, a rectifier and a threshold value detector. If a dial tone signal is received by means of such a detection circuit, which dial tone signal lies within the pass band of the band filter, the transmitted signal will be rectified and, if the rectified signal is of sufficient strength, the threshold detector will produce a dial tone detection signal. hand off. Such known dial tone detectors place very strict demands on the quality of the band filter and in particular on the exact shape of the pass band, because in fact only this band filter determines which signals will or will not reach the subsequent stages. Each of the signals passed through the bandpass filter, if of sufficient strength, leads to a dial tone detection signal. In practice, this means that relatively complex higher order filter circuits must be used to meet the often stringent requirements of a telephone system. This implies that such filter circuits are relatively expensive and complicated and difficult to adjust and maintain. In addition, such filter circuits suffer from varying component values.

The object of the invention is now to at least partly eliminate these drawbacks.

This object is accomplished according to the invention by providing a dial detector including a high-pass filter and a low-pass filter which together determine the frequency band within which the dial tone signals may occur, a comparator which transmits only signals within this frequency band above a predetermined threshold value, and a frequency comparator that determines the frequency of the transmitted signals and outputs a dial tone detection signal if a dial tone signal of the correct frequency occurs for a predetermined period. Using the high-pass filter and the low-pass filter, a first coarse selection 8402260 1 2 is made from the incoming signals. The comparator then passes only those signals that have sufficient strength to be a dial tone signal. Subsequently, the final selection between dial tone signals and possibly other still transmitted signals 5 is made in the frequency comparator, which only produces a dial tone detection signal when signals of which the frequency is within predetermined limits, which signals also occur over a sufficiently long period, are received. This achieves that the requirements to be imposed on the low-pass filter and the high-pass filter can be considerably less stringent than is the case in the prior art. Within the scope of the invention, therefore, a first-order filter circuit can be used for the high-pass filter, while a second-order filter circuit is preferably used for the low-pass filter. Both types of filter circuits can be realized in a very simple manner without adjustment with the aid of operational amplifiers and inexpensive components.

In those cases where dial tones can occur within multiple frequency ranges, for example dial tones from the normal telephone network in a first frequency band as well as dial tones generated internally in a home telephone exchange within a second frequency band, it is preferable that the frequency band determined by the filters covers both the external dial tone and the dial tone applied internally in home exchanges.

In one embodiment of the invention, the frequency comparator can each time determine the period that passes between consecutive similar edges of the signal applied to it and then compare these measured periods with predetermined limits that define one or more nominal frequency ranges. The frequency comparator may further be arranged to count the number of consecutive periods within one of the nominal frequency ranges after which a dial tone detection signal is output if this number exceeds a predetermined number.

In a preferred embodiment of the dial tone detector according to the invention, the frequency comparator is implemented by means of an appropriately programmed processor, performing the following steps: a) waiting for a first edge to occur at the input of the processor, b) measuring the period that elapses to the next edge at the 40 input, comparing the measured period with predetermined limit 8402260 3

V

Grounding and repeating step b) if the measured period is outside the limit values, b ') measuring the period that elapses to the next edge at the input, comparing the measured period with predetermined limit-5 values and repeating step b) if the measured period is outside the limit values, c) determine whether a period between two flanks falling within the predetermined limit values occurs within a predetermined time and repeat step b) if not, 10 d) outputting a dial tone detection signal if the processor sequentially performs step c) for a predetermined period *

The invention will now be explained in more detail below with reference to a practical exemplary embodiment, illustrated in the accompanying figure 1. Figure 2 further shows a diagram explaining the operation of the circuit of figure 1 *

Figure 1 shows a dial tone detector according to the invention, composed of four operational amplifiers (arranged in one housing in this example) and a microcomputer * The operational amplifier IC 3a of type 3403 together with the associated components 20 form R13, R14 and C9 , C17 is a first order high pass filter of a known per se configuration. The output of IC 3a is applied to a second stage built around the operational amplifier IC 3b. A second order low-pass filter is realized in this second stage of the circuit together with the accompanying components R15, R16, R17 and CIO, C11 and C18. The configuration of this second-order low-pass filter is also assumed to be known to the person skilled in the art.

The output signal of this low-pass filter is supplied via a coupling capacitor C21 to a third stage built up around IC 3c.

Together with the associated components R18, R19, R24 and C19, this stage forms a comparator circuit which only transmits signals above a certain threshold level, which threshold level is dependent on the hysteresis in the comparator circuit. In the illustrated configuration, this threshold level is about 60 mV of the original signal generated by the generator in the telephone network. The output of the IC 3c is terminated with a load resistor R32. The output of this stage is applied to a suitable input of the processor IC 1 for further processing therein.

The remaining components, namely the integrated circuit IC 3d, the capacitor C20 and the resistors Ril and R12 form an 8402260 4 voltage stabilization circuit for a reference voltage.

The processor IC 1 is connected via an address bus 17 and a data bus 18 to a memory IC 2. Although the figure shows a single memory IC 5, in practice this may, for example, be a programmable read-out memory in which a program is stored combined with a random access memory in which intermediate results of the calculations performed by IC 1 can be stored and recalled. These and other variants are within the scope of the invention.

Figure 2 shows in a voltage-frequency diagram in the first place within which frequency limits the cloning signals can occur, at least according to Dutch standards. Dial tone signals can occur within the frequency range 20 between 100 Hz and 200 Hz and within the frequency range 21 between 350 Hz and 550 Hz. For 15 tone signals in the region 20, signals within this frequency range with a voltage of more than 140 mV must be recognized as a dial tone with certainty. Signals within the frequency range 21 with a voltage greater than 80 mV must certainly be recognized as a dial tone signal. Furthermore, for each frequency, signals with an amplitude less than 40 mV may not be recognized with certainty. Based on these specifications, the designer is therefore free to draw a limit in the no-man's-land between 40 and 140 mV for the frequency range 20 and between 40 and 80 mV for the frequency range 21 himself.

In the circuit of figure 1 the total circuit around IC determines

3a and IC 3b a filter circuit, the characteristic of which is indicated by 22 in Figure 2. The first order high-pass circuit is mainly responsible for the slowly falling characteristic in the lower frequency part, while the second order low-pass circuit around 30 IC 3b is responsible for the relatively sharply rising part at higher frequencies.

Figure 2 shows that by choosing a first-order high-pass filter with a second-order low-pass filter, a relative adaptation is obtained to the different limit amplitudes of 140 to 35 mV for the area 20 and 80 mV for the area 21 above which the selection signals must be guaranteed. be recognized.

Depending on the associated components, the comparator around IC 3c is set so that this comparator has a hysteresis sufficient to ensure that signals with an amplitude less than 40 mV are not transmitted. This satisfies the corresponding requirement that signals below 40 mV should not be detected as dial tone.

The comparator output is applied to the processor IC 1 which under the control of a program stored in IC 2, 5 functions as a frequency counter in the manner to be described below.

In the circuit, a distinction is first made between four different states in which the circuit can be, namely: 10 - NO TONE: no tone has yet been detected - CHECK TONE: in this state, it is checked whether at the input 16 of IC 1 a period occurs corresponding to a frequency between 100 and 550 Hz.

- DETECT TONE: in this state it is checked whether a subsequent edge occurs within the legal period duration.

- TONE: in this state it is checked whether the occurring signal has a sufficiently long duration to be recognized as a dial tone.

As long as there is no signal on input 16 of processor IC 1, the state is NO TONE. In that case, no output signal 20 will appear on the output 15 of the processor.

As soon as a rising edge (the start of a possible period) is detected on input 16, the state changes to CHECK TONE, in this state to measure the period duration until the next rising edge.

If a further rising edge occurs at the input 16, there are two possibilities: - the period duration between the two edges falls within the limits associated with a tone which lies in the range between 100 and 550 Hz. In that case the so-called legal period duration is involved and the circuit 30 switches to the next state DETECT TONE to determine the duration of the subsequent period until the occurrence of the third rising edge.

The period duration is outside the set limits and in that case the circuit remains in the CHECK TONE state and will therefore again measure the period until a next rising edge occurs. However, if the next rising edge remains off for more than 30 ms, the circuit returns to its original state NO TONE.

In the DETECT TONE state, another rising edge again leads to two possibilities: 40 - the next rising edge occurs within the legal period duration in which 8402260 4; > v 6 the circuit changes to the last state SHOW; - the next rising edge does not occur within a legal period duration, in which case the circuit returns to the CHECK TONE state. If the next rising edge remains off for more than 30 me, the circuit returns to the initial state NO TONE.

The TONE state is maintained as long as a new period is recognized with the legal period duration within 30 ms of recognizing a legal period duration. If such a period is not recognized within 30 ms, the initial state NO TONE is restored. If, however, the TONE state is maintained for 1000 ms, then the detection of a dial tone signal is thereby completed (at least during automatic dialing, during reading along with manual dialing, 200 ms is sufficient) and a corresponding output signal is output via an output 15 to that end in the Figure does not illustrate suitable means.

It is noted that the circuit according to the invention is of course also applicable if the nominal requirements with regard to times, frequency location and amplitude, illustrated in figure 2 for the Dutch example, deviate therefrom in other telephone systems. Multiple-20 frequency bands can be detected separately. For each band, a unique output signal can be output both outside the processor and inside the processor to other program components.

Figure 1 shows specific type numbers for a number of components. For example, the operational amplifiers may be housed in a single integrated circuit of type 3403. The processor IC 1 may be, for example, a type 80C49, the input 16 being, for example, the interrupt input on pin 6 and the output 15 being, for example, formed by the output port connected to pin 29.

It will be clear, however, that the component values and component specifications indicated in the figure only apply to a particular application example and that within the scope of the invention all kinds of other operational amplifiers and other settings can also be used depending on the circuit to be used. set 35 requirements.

8402260

Claims (9)

1. Clone detector provided with a high-pass filter, a low-pass filter which together determine the frequency band within which the dial tones can occur, a comparator that only transmits signals within this frequency band above a predetermined threshold value and a frequency counter with which the frequency of the transmitted signals is determined and outputting a signal if a dial tone frequency occurs for a predetermined period. Clone tone detector according to claim 1, characterized in that the high-pass filter is a first-order pass filter. Clone detector according to claim 1 or 2, characterized in that the low-pass fliter is a second-order filter circuit. Clone tone detector according to any one of the preceding claims, characterized in that the frequency band determined by the filters covers both the external dial tone and the internal color tone used in home exchanges. A clone detector according to any one of the preceding claims, characterized in that the frequency comparator determines the period which elapses between successive similar edges of the applied signal and compares these periods with predetermined limit values which determine one or more nominal frequency ranges. 6. Clone detector according to claim 5, characterized in that means are provided for measuring a predetermined period of time and outputting a signal at the end thereof if within the said period of time the frequency comparator successively has similar edges within said limit values. are found. Clone detector according to claim 6, characterized in that the frequency comparator is implemented by means of a suitably programmed processor with which the following steps are performed: a) waiting for a first edge to occur on the input b) measuring the period that elapses up to the next edge at the input and comparing the measured period with predetermined limit values and repeating step b) if the measured period is outside the limit values, b ') measuring the period until on the next edge at the input and comparing the measured period with predetermined limit values and repeating step b) if the measured period is outside the 40 limit values, 8402260 * · ί ~ 'V c) determine whether each within a predetermined time a period between two edges occurs which falls within the predetermined limits and repeating step b) if not d) outputting a dial tone detection signal indi and the processor executes step c) for a predetermined period successively. Dial tone detector according to claim 7, characterized in that the predetermined period mentioned under step c) is equal to 30 ms. Dialing tone detector according to claim 7, characterized in that the predetermined period mentioned under step d) is equal to 200 ms during read-in and 1000 ms during automatic dialing, respectively. ******** 8402260