FR2529426A1 - Digital tone generator for telephonic signalling - requires controller to signal loading of memory with frequency sample data and subsequent output of selected frequency - Google Patents

Abstract

A switching controller issues signals on a bus to a decoder to signify when a particular frequency is to be generated. The decoder provides address information for locations in a memory in which series of digital samples of the different frequencies. A modulo N counter incremented by a clock signal delivers addresses of the different samples of the same sequence to the memory. A modulo 8 counter is incremented by another clock signal to issue addresses corresponding to the binary elements of the same digital sample. An interface converts the data bus from the controller into address and data busses. This permits loading of the memory with a frequency from the controller. A three state gate at the memory output is enabled by the controller to issue a selected frequency on a PCM bus.

Description

FREQUENCY GENERATOR USED IN
A digital time switch
The present invention relates to a frequency generator used in a digital time switch.

 During or before a conversation between two analog terminations, it is often necessary to transmit frequencies either from one or the other of these terminations to the automatic exchange, or from the automatic exchange towards one or the other of these endings. These frequencies consist, for example, of a dialing signal or a dialing invitation, ringing, call return, busy, error, etc. tone.

 All of these tones are usually single or double frequency. In practice, the values of these frequencies are either multiples of 10 Hz (this is the case for example for the various aforementioned tones and for the multifrequency codes R2 and MF Socotel) or particular values not multiples of 10 Hz (c ' is the case of the multifrequency code Q 23). Thus, the MF Socotel code uses the frequencies 700, 900, 1100, 1300, 1500, 1700 Hz and 1900 Hz, the R2 code two groups of six frequencies: 1380, 1500, 1620, 1740, 1860 and 1980 Hz on the one hand , 1140, 1020, 900, 780, 660 and 540 Hz, on the other hand, and the code Q 23 two groups of four frequencies: 697, 770, 852 and 941 Hz on the one hand, 1209, 1336, 1477 and 1633 Hz on the other hand. As for the tones, they have frequencies 330, 350, 440, 480 and 620 Hz.

 All these frequencies must be generated with the greatest possible precision, the maximum tolerated error generally being of the order of + 0.5%, except for code Q 23 where the accepted error is of + 1.5%.

 In a digital time switch, these frequencies must be generated according to the technique of. pulse code modulation (MIC), that is to say in accordance with international standards, in the form of samples of eight binary elements, these samples succeeding each other at the sampling frequency F (F being equal to 8 kHz) and the binary elements being transmitted in serial form at the rate of 2.048 MHz or 1.544 MHz (depending on the country). This technique makes it possible to multiplex 32 or 24 time intervals, depending on the country, on the same transmission medium.

To generate according to this technique the different frequencies used by the automatic exchange, it is therefore necessary to sample these frequencies, to code the samples on eight binary elements, and to memorize the bytes, or digital samples, thus obtained. Given J the periodicity of the signals to be generated, it is sufficient to store for each frequency f a number of bytes equal to the integer "nit 'closest to the ratio Fr, the difference between fur and the integer most
of F close to being representative of the error made during the generation of this frequency. These bytes are stored in sequential form in a memory and the addressing system of this memory necessarily includes a "modulo n" counter activated by a signal clock of frequency equal to the sampling frequency F. The value n being different for each of the frequencies to be generated, we are naturally led, according to the conventional solution, to provide either as many memories and as many addressing counters of these memories as frequencies to be generated, ie a single memory with as many addressing counters as frequencies to be generated and with a member for selecting one of these counters as a function of the frequency to be generated.

 The object of the present invention is to substantially reduce the number of components required for the generation of the different frequencies used in a digital time switch.

By means of a simple adaptation of the number of bytes stored for each of the frequencies, the frequency generator according to the invention now only requires a single memory and a single addressing counter common to all of the frequencies to be generated.

 According to the invention, the frequency generator used in a digital time switch includes a memory in which are stored sequences of digital samples representative of the different frequencies to be generated and an addressing circuit of this memory itself comprising a circuit d addressing of the samples of each of these sequences, the number of digital samples of each sequence being fixed and equal to N (with N integer) and the circuit of sequential addressing of the samples of each sequence comprising a single modulo counter N .

 The objects and characteristics of the present invention will appear more clearly on reading the following description of an exemplary embodiment, said description being made in relation to the attached drawing representing a frequency generator according to the invention.

 The frequency generator shown in the figure includes a memory 1 in which are stored sequences of digital samples representative of the different frequencies to be generated. We have symbolically delimited these different sequences in the figure. using horizontal lines dividing memory 1 into as many zones as frequencies to be generated.

 The number of digital samples in each sequence is fixed and equal to N (with N integer), the value N being determined as will be seen later.

 The addresses of this memory come from an address bus 2 comprising three sets of wires.

 A first set of wires comes from a circuit 3 delivering the addresses corresponding to the different suites.

 A second set of wires comes from a circuit 4 showing the addresses corresponding to the different digital samples of the same sequence.

 A third set of wires comes from a circuit 5 delivering the addresses corresponding to the different binary elements of the same digital sample. In fact, in the embodiment described, the memory 1 is a word memory of a binary element and the data are available in serial form on a transmission bus 6 MIC connected directly to the output of the memory 1. If the memory 1 was a word memory of eight binary elements, circuit 5 would be useless and the outputs of memory 1 would be connected to bus 6 via a parallel-serial converter activated by the clock signal h.

 The circuits 3, 4 and 5 form a circuit 5 'for addressing the memory 1.

 The circuit 5 is a modulo eight counter, called the counter for addressing binary elements, incremented by a clock signal h of frequency equal to the frequency of transmission of the binary elements on the transmission bus 6 MIC.

 Circuit 4 is a modulo N counter, called a sample addressing counter, incremented by a clock signal H of frequency equal to the sampling frequency F.

 Circuit 3 is a decoder which receives on a bus 7 the address of the sequence to be generated. The control unit of the automatic exchange (not shown in the figure) having previously chosen a time interval for the emission of a frequency, the address of the sequence to be generated is provided on the bus 7, during this interval of time. The PABX control unit supplies at the same time as this address, on a wire 8, the control signal of a three-state output door 9 connected to the memory output 1. This allows the transmission of the selected sequence, on the MIC transmission bus 6, during the time interval selected by the control unit of the automatic exchange.

 Unlike conventional systems in which the different frequencies are generated cyclically, even if they are not used, on a transmission medium (MIC bus or time interval of a MIC bus) specialized in the transmission of these different frequencies, and in which the switching of these different frequencies on the other transmission media in MIC mode is done within the connection network under the control of the control unit of the PABX, this addressing system for the different sequences of digital samples has the advantage of not reserving a transmission medium for the transmission of the different frequencies usable by the automatic branch exchange, that is to say of increasing the capacity of the automatic branch exchange. The present invention uses time intervals only for the frequencies to be generated at this time.

 In the figure there is also shown an interface 10 capable of transforming a data bus 11 coming from the control unit of the automatic branch exchange into an address bus 12 and into a data bus 13 respectively connected to bus 2 and to a bus 14. This makes it possible to load the memory 1 with any frequency from the control unit of the automatic exchange. Buses 2 and 12 constitute the address bus of memory 1, while buses 13 and 14 constitute the data bus of this memory.

 We now explain how to determine the number N of digital samples common to all of the sequences stored in memory 1.

F
Let n be the integer closest to the ratio f where F denotes the sampling frequency and f any frequency to be generated. The number n constitutes the minimum number of samples to memorize in order to be able to generate the frequency f. If we now wish to have a number N of samples, with N integer, which is the same for all the frequencies f to be generated, this number N must be greater than F, the ratio Nf then designating the number of times the frequency f will be generated (number of periods) when reading the corresponding series of samples in memory 1. To obtain a correct synthesis of the different frequencies, it is necessary that the beginning and the end of each portion of frequency sine f stored in the form of a series of N samples
Nf numerical are in phase, that is to say that the report F is whole. The f number N (with N integer and f integer or not) must therefore be chosen so that, whatever the frequency f to be generated, Nr is integer, or otherwise as close as possible to an integer.

f
If the values N, f and F (with N integer and F integer or not) are such that whatever the frequency f to be generated, Nf is integer, the error r made during the generation of the frequencies f is zero.

For example, for frequencies to generate f multiples of 10 Hz and for a sampling frequency F equal to 8 kHz, the number of samples N is advantageously chosen equal to 800. It should be emphasized that any value multiple of 800 would also be suitable, the only difference being the volume occupied by memory 1. For these particular values, the error in the generation of frequencies f is zero. Indeed the ratio Nf is then equal to 10,, and by hypothesis f is multiple of
10 10 Hz. For these particular values counter 4 is a counter with ten binary elements which is reset to zero when it reaches the value 800, or which, for a more economical practical realization, counts up to 1024 and is then loaded to the value 224 as the start of counting.

If there is no value N such that whatever the frequency f to
Nf f generate, the ratio Nr (with N integer and F integer or not) is integer, the number N must be chosen so that whatever the frequency f to Nf generate, r-is as close as possible to an integer , the difference between this integer and NFfre then representing the error committed during the generation of the frequency f.

Let f. one of the frequencies to be generated and 8 the maximum error tolerated on this frequency. The number or samples to be memorized per period is such that:

If we wish to reproduce the period K. times in a sequence, we obtain:

 The product Ki ni is equal to N, that is to say the number of samples in the series.

We thus obtain a system of inequalities for frequencies f. to generate:

This system of k inequalities with k + 1 unknown shows that there are an infinity of solutions. Indeed if N samples verify this system, 2 N, 3 N, etc ... also verify this system.

 A constraint on N can be given by the manufacturer depending on the size of the memory used.

 For example if we use a memory box of 64 K words of 1 binary element to generate 16 different frequencies the maximum number N will be: N # ####, that is to say N # #####, ie N # 512 where the number 16 represents the 16 frequencies to be generated and the number 8 the number of binary elements per MIC sample.

By way of example, when the frequencies f to be generated are the frequencies constituting the multifrequency code Q 23, and when the sampling frequency F is equal to 8 kHz, the number of samples
N is advantageously chosen equal to 508. The error in the generation of the frequencies is then less than + 0.6%. For these particular values, the counter 4 is a counter with nine binary elements which counts up to 508 and is then reset to zero, or for a more economical realization, counts up to 512 and is then loaded at the value 4. Any multiple value of 508 would also lead to a maximum error of + 0.6%.

 With a number N of samples between 500 and 510, or between any multiple of 500 and 510, the maximum error would be + 1%.

 With a number N of samples between 374 and 512, or between any multiple of 374 and 512.1, the error would be + 1.5%.

Claims (9)

 1. Frequency generator used in a digital time switch, comprising a memory (1) in which are stored sequences of digital samples representative of the different frequencies to be generated, and an addressing circuit (5 ') of this memory itself comprising a sequential addressing circuit for the samples of each of these sequences, characterized in that the number of digital samples in each sequence is fixed and equal to N (with N integer) and in that the circuit of sequential addressing of the samples of each suite includes a single modulo N counter (4)  2. Generator according to claim 1, in which F denotes the sampling frequency defining the automatic switch, characterized in that the number N common to the set of frequencies to be generated is such  Note that for any frequency f to be generated, the ratio F is an integer, the error on the frequencies to be generated then being zero.  3. Generator according to claim 2, in which the sampling frequency F is equal to 8 kHz, and in which the frequencies to be generated are multiples of 10 Hz, characterized in that the number N is equal to 800 or to any multiple of 800.  4. Generator according to claim 1, in which F denotes the sampling frequency defining the automatic switch and b the maximum tolerated error on the frequencies to be generated, characterized in that the number N common to all frequencies to be generated checks, for any frequency f to be generated, the following inequality: KF / f (1 + #) # N # KF / f (1- #), where K is an integer.  5. Generator according to claim 4, in which the sampling frequency F is equal to 8 kHz, and in which the frequencies f to be generated are the frequencies constituting the multifrequency code Q 23, characterized in that the number N is equal to 508 or any multiple of 508, the maximum error on the frequencies generated then being + 0.6%.  6. - Generator according to claim -4, - in which - the sampling frequency F is equal to 8 kHz, and in which the frequencies f to be generated are the frequencies constituting the multifrequency code Q 23, characterized in that the number N is between 500 and 510, or between any multiple of 500 and 510, the maximum error on the frequencies generated then being + 1%.  7. Generator according to claim 4, in which the sampling frequency F is equal to 8 kHz, and in which the frequencies f to be generated are the frequencies constituting the multifrequency code Q 23, characterized in that the number N is between 374 and 512 or between any multiple of 374 and 512, the maximum error on the frequencies generated then being + 1.5%.  8. Generator according to one of claims 1 to 7, in which the automatic switch includes a control unit, characterized in that the memory addressing circuit (1) also includes a decoder (3) which receives control unit the address of the sequence to be generated, a three-state output door (9), controlled by the control unit, being provided at the output of the memory (1).  9. Generator according to one of claims 1 to 8, wherein the automatic switch includes a control unit which communicates with the outside by means of a bus (7), characterized in that it comprises a circuit write memory (1), itself comprising a decoder (10) which transforms the bus (7) into an address bus (12) and into a data bus (13) of memory 1.