DE2261971A1 - TEST DEVICE FOR TELEPHONE SETS WITH PUSH BUTTON SELECTOR - Google Patents

Description

Test device for telephones with pushbuttons enselector The invention relates to a device for testing an audio frequency selection signal generating mechanism of a push-button dialer telephone.

In addition to the normal telephones, there has recently been a push-button dialer telephone come into use with an audio frequency selection signal generating mechanism for Generation of an audio frequency selection signal. It is an indispensable condition for a telephone that uses the frequency dialing mechanism of a push-button dial telephone has a normal function and it is from the production control point of view and maintenance is also required, a simple and precise reliability test of the audio frequency selection signal generating mechanism to be able to perform. So far, however, it has not been satisfactory Test facility for be delivered for this purpose.

It is therefore the object of the invention to provide a test device for a To create push-button dialer telephone with which the normal function and the visually Reliability of the phone can be determined exactly.

Principle, structure and mode of operation of the invention are now in individual in the description of an exemplary embodiment shown in the drawing the invention explained. 1A shows a black diagram which shows an embodiment in FIGS Figure 1B reproduces the game of the invention; Fig. 2 time sequences in diagram representation for Explanation and 3 explanation of the mode of operation of the exemplary embodiment in FIG. 1; Fig. 4 a block diagram of a specific embodiment of a reference time generating Circuit used in the invention; Fig. 5 is a timing diagram for Explanation of the mode of operation of the circuit from FIG. 4; Fig. 6 is a waveform diagram; which reproduces the operation of the circuit of FIG. 4; Fig. 7 is a circuit diagram of a specific embodiment of a shift pulse generator used in the invention is applied; Fig. 8 is a waveform diagram for explaining the circuit Fig. 7; 9A shows a circuit diagram of a concrete exemplary embodiment a decoder used in the invention; 9B are diagrams showing a Siebenseg and 10B ent imaging patterns for use in the invention; and Fig. 10A is a circuit diagram of one embodiment of a decoder driver for use in the invention.

First of all, a description should be given of an audio frequency selection signal, generated by a push button selector.

In a pushbutton dialer telephone, pushbuttons that represent the digits 0 to 9 and other symbols, optionally pressed, so that they carry signals from certain Generate frequencies that correspond to the respective pushbuttons pressed, whereby a desired participant called in a voter arrangement or other operations be made. The push button dial phone can have three high frequencies and four generate low frequencies, and become a high frequency and a low frequency generated by pressing one of the pushbuttons at the same time. Any of the digits 1 to 9 or the other symbols are decisive for the combination of two signals of these frequencies. Currently owned by Nippon Telegraph and Telephon Public Corporation Standardized push button dial telephones use combinations of frequencies, such as they are shown in Table 1 below.

TABLE 1 Frequency High frequency range (Hz) 1209 1336! 1477 697 1 2 3 Low- 770 4 5 6 ger 852 7 8 9 Frequency 941 ROB area An example of a construction of a test device according to the invention for testing a telephone having such a push-button dialing mechanism as described above will now be described in conjunction with FIGS. 1A and 1B. In FIG. 1A, 1 denotes a push-button telephone which is to be tested and which is connected to the input terminal 2 for the purpose of testing. The input terminal 2 is connected to an ordinary energy source via a load resistor 3. The load resistor 3 is used to ensure that the pushbutton telephone 1 receives a certain voltage, and that a signal of a standardized frequency, which is generated in the Telebnapparat 1, is fed to a subsequent amplifier 4 as a voltage change. The signal fed to the amplifier 4 is sufficiently amplified, and part of the amplified output is fed to a high frequency rejection filter 5, while another part is fed to a low frequency notch filter 6.

The high frequency rejection filter 5 prevents signals from passing through with a frequency of more than 1,000 Hertz, however, lets signals of frequencies below 1,000 Hertz. In contrast to this, the band-stop filter 6 blocks low Frequencies the passage of signals with frequencies below 1,000 Hertz while Signals with frequencies in excess of 1,000 hertz are allowed to pass if so the push-button dialer telephone 1 a signal consisting of the combination of a high frequency and a low frequency ten tones, then the signal is passed through the high frequency rejection filter 5 and it blocks the low frequencies in signals of the high frequency and the lower divided into frequency groups The outputs of filters 5 and 6 are the inputs of Waveform regeneration circuits 7 and 8 are supplied, at the outputs of which the pulse signals v5 and v6 occur with a steep rise and a steep fall, their fundamental frequencies are the same as those at the entrance. These pulse signals v5 and v6 to serve to operate the following digital circuits.

In FIG. 2, the output variables of the amplifier 4 are the filter 5 and 6 and waveform regeneration circuits 7 and 8 are shown. The exit signals V5 and v6 from waveform regeneration circuits 7 and 8 are each assigned to one input the gates 9 and 10 are given. A reference time signal v7 @ das in a reference time circuit 11 is generated, comes to the other input of gates 9 and 10. Since the gates 9 and 10 designed as AND gates let the signals v5 and v6 from the Mnds Waveform regeneration circuits 7 and 8 only happen when the reference time signal v7 has the digital state "1" t. The gates 9 and 10 leave their outputs the pulses emanating from the waveform regeneration circuits 7 and 8 within eng Reference time T.

This is shown in FIG. 3. The frequencies of the filters 5 and 6 derived signals can thus be determined by counting the number of pulses that have passed through the gates within the reference time T.

Counters 12 and 13 are circuits for counting the pulses. The counters 12 and 13 are formed by cascading flip-flop circuits, and these Counters 12 and 13 count the pulses in binary form so that their output values are in binary code Show. The outputs of counters 12 and 13 are connected to decoder drivers 14 and 15, in which the binary codes are converted into decimal codes or the for To drive can be used by seven segment integrators.

The outputs of the circuits 14 and 15 go to integrators 16 and 17, where you can display digits according to the number of pulses.

So a sound signal, a high frequency signal and a signal low frequency and generated in the pushbutton selector tel'fcr l split up into signals of the high-frequency and the low-frequency group, which in turn Nuirric display of the frequencies of the low and high frequency groups on the Causing integrators 16 and 17 for the low and the high frequency at the same time.

As shown in Fig. 3, the reference timing generator circuit 11 also generates a reset signal v9. The reset signal vg is used to reset the counter 12 and 13 in their initial state, that is to say the state "O", in which on the integrators the ads are in place. So if at the beginning of the reference time T the reset signal is generated, the counters then begin to count from the "O" state.

The output terminals T la and T2a of the filters 5 and 6 are shown in Fig. 1B is connected to terminals Tlb and T2b, and the output signals of the filters become a band pass filter group 18 supplied. Task of the bandpass filter group 18 is to let signals of a certain frequency through. For the embodiment described it is assumed that the signals generated by the push button dial telephone are those are as shown in Table 1, and the band-pass filter groups 18 are included Filters with center frequencies of 679 Hertz, 770 Hertz, 852 Hertz and 941 Hertz in of the low frequency group as well as 1 209 Hertz, 1 336 Hertz and 1 477 Hertz in the High frequency group. When one of the dial buttons of the push button dial telephone 1 is pressed becomes signals of a certain higher frequency and a certain lower frequency Frequency generated and separated by the filters 5 and 6 and then the Bandpass filter groups 18 supplied. The signals of the higher and lower frequency groups pass one of four low-band pass filters and one of three high-band pass filters. The signals that have passed the band-pass filter group 18 reach the detector group 19 and are converted into DC voltage signals there. When a signal that has passed through one of the filters of the bandpass filter group 18 is present then takes the output of a detector connected to this bandpass filter is, the state 1, while the outputs of the detectors with bandpass filters connected through which no signals have passed through the Assume state "0".

The output from the detector group 19 is given to a decoder 20 When the push button (1) is pressed, tone signals with frequencies 1 209 Hertz and 697 Hertz generated, as can be seen from Table 1, so that the Signals pass through the filters ~ HFl and LE1 of 1 209 Hertz and 697 Hertz, so that the outputs of detectors 19-5 and 19-1 connected to the filters are, assume the states "1", while all outputs of detectors that are connected to the other filters, assume the status "0". The decoder 20 performs a code conversion when generating such a signal and sets the number (1) is shown on the driver and number indicator 22.

The output of the decoder 20 is connected to the input of a shift register 21 connected. The shift register 21 can store a variety of signals, which are generated by several keystrokes on the push-button dialer telephone 1, so that the signals are displayed on the indicator 22 at the same time. For example, if the pushbutton (1) of the pushbutton dialer telephone 1 is pressed, the input Each first stage of the shift register 21 is given a signal. If then through Pressing the pushbutton (1) the signal received is completely recorded, a «shift pulse v10 generated by the shift pulse generator 23, whereby every first stage is placed in the state that corresponds to the push button (1). Then becomes the pushbutton (2) of pushbutton dialer telephone 1 is pressed, 80 your signal comes on the input each first stage of the Scheregi star 21, during the state of each first stage simultaneously with the generation of the next shift pulse v10 in the second stage is pushed. This is the signal generated by pressing the push button (2) introduced into the first stage. In the illustrated embodiment is a Ten-stage shift register 21 provided so that signals that by pressing ten times of the pushbuttons can be generated, saved and displayed at the same time.

The output of the shift register 21 is with a driver. and number indicator 22 connected. The illustrated embodiment uses seven segment indicators, so that seven parallel shift registers are required. Every first stage of the Shift register 21 is with the rightmost stage of the driver and Number indicator 22 connected, while the second »third etc. stage of the shift register 21 in sequence with the corresponding levels of the driver and number indicator 22 connected to the lie further to the left. The purpose of this is that the number 22 evoked by the first push of a button is on the left Side of the indicator / appears as the most significant digit.

Referring next to Figures 4 and 5, a actual embodiment of a reference timing generator circuit 11 is described will. FIG. 5 shows timing diagrams of signals at points shown in FIG. 4 are labeled A to K. The operation of the reference time generating circuit 11 is described below. First, a reference timing pulse generator generates 41 reference timing pulses val; with pulse intervals of 0.2 sec, what line a in Fig. 5 indicates. These reference timing pulses vll with 0.2 sec interval are on in the following way. A 100 KHz sinusoidal signal generated by a transistor oscillator is generated, which a DT cutting crystal oscillator of for example 100 KHz is first converted into pulses of the same repetition frequency. The 100 KH'z pulses are generated through four stages of a 1 / 1Q frequency divider circuit up divided to a frequency of 10 Hz. Then the 10 Hz signal is passed through a 1/2 frequency divider brought to 5 Hz. These impulses are called pushing impulses perpetual the slide control star 42 and 51 fed.

That by pressing a pushbutton on the pushbutton dialer phone 1 generated signal of v1 comes to an input 60 of the reference time generating circuit 11 through the amplifier 4. This signal vl is through a rectifier and smoothing circuit 52 rectified, so that at point C there is a waveform vl2 as it is in Fig. 5 in line C is shown. The signal v12 is generated by a reshaping circuit put back into its correct shape, this circuit being a NOT circle 53 and two NAND circuits 54 and 55. The signal at their output v13 is with D in FIG. 5. The mode of operation of the pulse shaping circuit is switched on described later. The waveform v13 at point D comes as a trigger input to a monostable circuit 56, for example a monostable multivibrator is. More specifically, the one-shot circuit 56 is activated by the leading edge of the signal v13 triggered and generates a pulse vl4 of a pulse width, which is determined by a time constant specified in the circuit. In which Embodiment, this time constant is set so that the pulse width is about 100 ns. This pulse v14 is under number E in Fig.

5 shown. The output of the monostable circuit 56 is to the release terminal CL of the shift register 42 and the presetting connections PS of the shift registers 43 to 51 are given.

When the signal v14 on the activation terminal CL of the shift register 42 comes, the output Q of the shift register 42 takes regardless of the signal level at the timer input CP a low level value "L". Also take through Input of the signal vl4 at the presetting inputs PS of the shift registers 43 to 51 whose outputs Q have a high level value "H", whatever level value they always have have CP at the timer input. When the contents of each shift register move one level is shifted to the right by the first timing pulse v11 D after the signal vl4 The outputs Q of the shift register are fed to each shift register 42 and 43 indicate the values "H" and "L", respectively. The Q outputs of the shift registers 44 to 51 however, remain unchanged and maintain the level value "H". When feeding the next Timing pulse v11 to each shift register becomes the content of the shift register 43. and 44 also changed from "L" to "H" and "H" to "L". The outputs of the other shift registers remain at the previous level value.

The shift registers 42 to 51 form a ring counter and its output is only diverted from registers 43 and 48.

The illustration shows that the outputs Q of the shift register 43 and 48 are routed to one input each of NAND circuits 57 and 58, respectively. If the Output The shift register 43 has the level "L" and the output of the shift register 48 is H, then the output value v7 of the NAND 'circuit 54 is Level value "H".

The output value V7 of the NAND circuit 57 is applied to an input of the Gates 9 (10), which is formed by a NAND circuit, so that then, if this signal has the level value H, the signal v5 of the frequency to be measured through the NAND gate 9 (10) to the input of the counter 12 (13), whereby it is counted. When the signal v7 is "L", the output is of the device 9 (10) always at the level value "H", and no pulse that is counted should, occurs.

The output v7 from the NAND circuit 57 is used as the input value of the fed to the monostable circuit 61, and when the output value V7 increases, the if its level "L" changes to H, it triggers the monostable circuit 61, so that the signal vg shown in the pulse timing diagram occurs at its output. This signal vg clears the counter 12 (13) so that the display shows 0 in every digit will.

Since the counter 12 (13) is instantly activated by the clear signal v9 from smaller pulse width is deleted, which is synchronized with the leading edge of the signal v7 occurs, the counter 12 (13) can determine the corresponding frequency of the Count signal v5 immediately after the clear signal vg.

The output with the level "H" at the NAND circuit 57 ensures that the signal v5 the NAND circuit 9 (10) can pass until the level at the Q output of the shift register 48 assumes the state "L", in other words to an output with level "L" from the shift register 43 to the shift register 48 after five timing pulses is shifted. The time for this passage is with that described exemplary embodiment for one second.

When the level at the output of the shift register 58 becomes "L", occurs the level at the output of the NAND circuit 57 from the state H is also "L", whereby it is prevented that the signal v5 can pass the gate 9 ([0). This will last as long prevented until the level at the output of the shift register 43 the value "L" after supply of five timing pulses and the time for it is with that described Filing example a second.

If the level at the Q output of the shift register 43 becomes "L", then the level of the signal v7 appearing at the point I becomes "H" while the signal vg the gate 9 (10) can pass and is counted. The counters and indicators are of course reset to zero by the clear signal immediately before the counting process begins.

The readout of the indicators 16 and 17 must be done within a counter display time take place during the reference time pulse, but the reading can be taken several times if the pushbutton on the phone to be checked is pressed continuously so that reading is not difficult. The counter display time and the reference time is both one second in the embodiment described, but they can be chosen at will by suitable selection of the number of shift registers, which are used in the Rizg counter, and the position of the output terminals that are derived from the Take out the ring counter.

If the input values to counters 12 and 13 are not too extreme counters on the right are shown, the display is reversed, and therefore is the output of an amplifier AMPk with the counter most to the right tied together.

Next, the pulse shaping circuit 7 and 8 will be described. if It is now assumed that the NOT circuit 53 and the NAND circuits 54 and 55 are able to measure levels above and below a value X in FIG. 6A Identifying "? L" and "H" as level values can produce an output on a large scale as shown in Fig.

6B is shown when there is an input showing 6A is this can be seen in the following table.

Table 2 NAND circuit 54 input Output above H. below HL Table 9 NAND circuit 55 input Output above L below LH Table 4 NAND circuit 54 input Output above L H below L Table 5 NAND circuit 55 input Output above HL below H. If the input value is below the point X, the input and output of the NAND circuits 54 and 55 are represented by Tables 2 and 3, the output from the pulse shaping circuit (output from the NAND circuit 54) being held at the level value 11. However, if the input value exceeds the value X, the inputs and outputs of the NAND circuits 54 and 55 are as shown in Tables 4 and 5 (there is of course a transition phase), so that the level at the output of the pulse shaping circuit then increases to the value " H "transferred.

The preceding description is in connection with the moment of the rise, but the same thing happens at the moment of the fall, so that no special description is necessary for it., It will now be in connection 7 and 8, the shift pulse generator circuit 23 is described.

The signal waveforms at each section of the shift pulse generator circuit 23 according to FIG. 7 are reproduced in FIG. An input signal v2, which is based on the Shift pulse generator circuit 29 is part of the output from the amplifier 4 and an alternating current with 2 frequency components, which through the Glel ¢ hrichter- and smoothing circuit is rectified, so that the signal v18 arises, and thereafter through an impulse forin, circled into a signal with a sharp rise and a sharp Waste is converted as indicated by s19. The rise of the signal v19 is used to trigger a monostable price 23-4, which in turn generates an impulse the duration12 eP7.eUgtw as indicated in v10. The duration t of the pulse corresponds to v10 a time constant determined by circuit constants C and R of the monostable circuit 23-4 is determined. In the case of the invention, this duration only needs to be long enough so that the presence of the signal can be determined by the detector 19. In response to the trailing edge of the pulse from of duration < generated by the monostable circuit 23-4, the content of each stage of the Shift register 21 shifted to the next following stage. The first stage receives the signal from detector 19 and the second stage the content of the first stage.

Next, the decoder 20 will be described. Figure 9A shows a preferred one AusfUhrungsbeispiel the decoder in the test device according to the invention is applied.

The decoder of FIG. 9 corresponds to the coding according to the table 1 constructed.

If the push button e.g. (1) is pressed, a signal with the two frequency components 697 Hz and 1 209 Hz generated by push-button dialer telephone 1, so that outputs from detectors 19-1 and 19-5 are 697 Hz and 1,209 Hz will. The output values from detectors 19-1 and 19-5 both come to one NAND circuit 20-1, but are the input conditions of the other NAND circuit not satisfied, so that the level "L" occurs only at the output of the NAND circuit 20-1, while the level ItHil is present at the output of the other NAND circuit. Since the Output level 11 from NAND circuit 20-1 is supplied to NAND circuits 20-2 and 20-3 output levels "are produced at the outputs of these NAND circuits. The "H" level signals become level outputs in inverters 20 and 20-5 "L" converted so that current flows in lamps b and c and these thereby light up. When the lights b and c light up, it is on the display device one (1) reproduced, which can be recognized by the seven segment pattern of Fig. 9B is.

When push button B (blue) is pressed, the will appear Detectors 19-4 and 19-7 output signals of 941 Hz and 1 477 Hz, while only an output value from the NAND circuit -20-6 has the level "L", so that a lamp i lights up, but not the other lights. A lamp i only lights up when one Push button R (red) is pressed.

If a push button of a slightly more complicated digit figure like (2) is pressed, the lights a, b, g, e and d light up, and the The decoder operates to display (2) on the display The elements denoted by "num; 1 and a 2" in the drawing are all NAND circuits Elements with # 3 are NOT circles or in other words are inverters in Fig. 9A the inputs of the NAND circuit 20-3, which are connected to the lamp c via the inverter 20-5 are connected, depicted that they are with the entrances of others NAND circuits are connected, but this is due to the structure of the decoder with NAND circuits with eight entrances; however, the NAND circuit 20-3 can also have nine inputs be equipped.

The decoder driver circuit 14 (15) and the display 16 (17) can have one Schaltun have structure, as shown for example in Fig. 10A. The circuit 14 (15) is a normal decoder driver and the display 16 (17) contains a diode matrix 16-1 (17-1) to form a number pattern that is based on the output values from the decoder driver 14 (15) and an indicator 16-2 (17-2). The display 16-2 (17-2) has seven lights and they are arranged so that the segments j1 to j7 form two superposed parallelograms, as shown in Fig. 10B. FIG. 10A corresponds to each of the counters 12 and 13 from FIG. 1A. In case of Figure 1A requires eight such sets. In other words every connection line, which runs from counters 12 (15) to decoder drivers 14 (15) contains lines S1 through 54 of decoder driver 14 (15) in Fig. 10Ar also includes each trunk from decoder driver 14 (15) of FIG. 1 ten output lines of the decimal decoder driver from Fig. 10A.

The test device according to the invention and in detail above has the following properties.

1. A push-button dial phone can be accurate with it in a short time being checked.

2. Since frequencies of the high group and low group frequencies displayed at the same time, the corresponding frequencies can also be displayed at the same time to be established.

3. As the number of each pushbutton of the pushbutton selector teleDns is separate is drawn by the frequencies, the testing of the telephone is also easy to carry out.

Claims (2)

PATENT CLAIMS 1. Test device for telephones with push-button selector, marked by combining the following features: Measuring connections (2) for connecting the Push-button dial telephone to be tested (1), which has an audio frequency signal accordingly selection information as a combination of a higher frequency signal and one of several signals of a lower frequency generated for feeding a specific one DC voltage to the telephone set and to receive a radio frequency dialing signal from the telephone set; a variety of filter detectors (18,19) attached to the measuring terminals (2) are connected and the signals of the corresponding frequencies from the audio frequency selector signals, which are fed to the measuring connections (2), filter out and determine; a Decoder (20) which is connected to the filter detectors (18, 19) to implement the determined output values of the filter detectors in corresponding parallel codes for displaying voter information; a plurality of parallel registers (21), which are connected to the decoder (20) and in which one after the other those from the output of the decoder received parallel codes in their parallel configuration are shifted after each audio frequency selector signal has been supplied; and a Display device (22) with the individual stages of a plurality of shift registers 21 is connected to display the voter information according to the parallel codes, which are represented by the combination of the states of the corresponding register levels will. 2. Testing device according to claim 1, characterized by a first and a second filter (5,6) which are connected to the measuring terminals (2) for discharge one group each of higher frequency signals and lower frequency signals from the audio frequency selector signal which is fed to the measuring terminals (2); a first and a second counter (12, 13) corresponding to the first and the second filter (5,6) are connected for counting the frequencies of the signals. lower frequency 4 lower frequency signals at the outputs of the first and second filters occur; a first and a second decoder (14,15), which are connected to the first or second counter (12,13) and which Convert digital output values of the first and second counters (12, 13) into parallel codes, the digits correspond to the corresponding frequency; and a first and no second Playback device (16, 17) connected to the first or second decoder (14, 15) are used to represent a large number of digits corresponding to those at the outputs of the first and second decoder's pending output signals from the frequencies of the higher frequency signals and the lower frequency signals.