DE1225235B - Circuit arrangement for pulsed sampling of alternating current signals, especially for channel distributors for the PCM - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H03k

German KL: 21 al-36/12

Number: 1225 235

File number: St 22898 VIII a / 21 al

Filing date: November 4, 1964

Opening day: September 22, 1966

• With impulse messaging or impulse control, it is necessary to use the signal that is in a series of digital signals is to be converted at certain sampling points or sampling times, that are spaced apart by a predetermined time and the electrical values that correspond to the correspondingly sampled values of the signal, for a further predetermined time or for a storage time that is shorter than the sampling interval. During this storage time the analog-digital conversion or the control process takes place. Have known signal sensing circuits various disadvantages, as will be discussed later in connection with FIG. 1 will be explained. In particular a transformer is needed in these circles, the presence of which the external dimensions and increases the price of the signal sampling arrangement. Furthermore induce the large sampling pulses or other large currents, which are necessary to control the switching diodes, noise in the neighboring ones Circuits.

In FIG. 1 shows a known circuit for sampling an analog signal and storing the value. This circuit is constructed in such a way that the analog signal which is present at input 11 is sampled every time a sampling pulse is present at input 12 . The values sampled at each sampling point are stored in a capacitor 13 until the charge stored in the capacitor 13 is discharged at the end of each storage interval, controlled by an erasing pulse applied to the input 14. The sampled values can be picked up at output 15. In this circuit are all the diodes of the switchable diode circuit 16, which acts as a switch for the transmission of the analog signal from the input 11 to the at each sampling time. Storage capacitor 13 is used during the times that lie between two sampling pulses, biased in the reverse direction. The sampling pulses arriving via the input 12 are amplified by the amplifier transistor 19 so that the amplified sampling pulses on the secondary side of the transformer 20 have a sufficiently large amplitude to overcome the reverse voltage applied to the switching diode circuit 16 and make the diodes conductive. Every time the diodes of the switching diode circuit 16 become conductive by a sampling pulse, the signal applied to the input 11 charges via the input resistance of the analog signal source, which is represented by a resistor 21 , the storage capacitor 13 with the time circuit arrangement for pulse-shaped sampling of alternating current signals , especially for
Channel distributor for the PCM

Applicant:

Standard Elektrik Lorenz Aktiengesellschaft,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

ίο named as inventor:
Hiroshi Kondo, Tokyo

Claimed priority:
Japan dated November 7, 1963 (60 068),
of January 18, 1964 (Figs. 4 and 5)

constant, which is determined by the input resistance of the signal source 21 and the capacitance of the storage capacitor 13 , to the voltage that the signal voltage has at the sampling time. At the end of each storage time, the erase pulse applied to input 14 causes the erase

a5 transistor 22 become conductive, so that the storage capacitor 13 is discharged until the voltage across it has dropped to zero, with a time constant determined by the capacitance of the storage capacitor 13 and the resistance of a current-limiting resistor 23 between the storage capacitor and the erase transistor 22 is set.

In this known circuit, the transformer 20 cannot be dispensed with, since the switching diode circuit 16 must not be connected to earth, except via the input 11 for the analog signal, via the quenching transistor 22 and via the output 15 for the sample. Furthermore, the considerably large electrical power which is necessary to actuate the switching diodes induces noise in the neighboring circuits.

Another circuit arrangement is known (German patent specification 812441) in which the switching diodes connected to earth. In this arrangement, too, the switching diodes are used to operate considerable power is required, which also induces noise in the neighboring circles and the undesired, large switching current is superimposed on the signal.

It is an object of the invention to provide a signal sampling circuit that does not have a transformer required and where the performance of the

609 667/363

3 4

Sampling pulses can be very small. The transistor 35 is the successive measure of the invention achieved in that as half-sampling pulses ν 12, the transistor 35 conductors two transistors are used to which block, so that the analog current signal is only applied while the signal to be sampled is applied , and that this of the periods of time between the successive transistors flows to earth as a function of the sampling signal 5 sampling pulses ν 12. It is also alternately blocked and switched through and that a third transistor 36 is provided, which also charges the output current from the transistor capacitor at its through-connected transistor, the emitter, and receives it through 32 through the other. The analog current signal from the first transistor connected to the transistor, the input signal short-circuit transistor 32, serves as a constant current source to be closed while the circuit is closed. Through the use of transi io each sampling time a constant current to the feeder as a switch is superimposed on the signal as a result of the cherkondensator 13 to be emitted. For this Trander current gain of the transistors a significantly sistor 36 is a bias voltage source 37 is present, smaller (unwanted) switching current than the bias voltage of the bias source 33 for El diodes. transistor 32 must be higher than the voltage

The invention is now based on the in the drawing 15 E 2 of the bias voltage source 37 for the third

Embodiments illustrated in more detail in the embodiments, since the base of the first transistor 32

purifies. It shows must lie on a higher potential than the base

Fig. 1 shows the circuit of a known already above of the third transistor 36. Furthermore, the span ₇

described scanning circuit, voltage £ 2 for the third transistor 36 greater than the

Fig. 2 is the circuit of a sampling circuit according to 20 maximum output voltage ν 15 that is at the output

of the invention, 15 may occur.

Fig. 3 shows waveforms taken at different points. The operation of the arrangement of Fig. 2 is shown

ten of the arrangement according to FIG. 2 occur now in connection with the in F i g. 3 "shown

Fi g. 4 explains the circuit of a further embodiment waveforms. In this figure is in the

according to the invention and '25 abscissa the time and in the ordinate the voltage

Fig. 5 shows the waveforms plotted at different amplitudes £. The analog signal voltage Points of the arrangement according to FIG. 4 occur. ν 11 (Fig. 3a) is positive to earth. These ■ In the F i g. 2 is an embodiment for a voltage is passed through the first transistor 32, whose Analog signal scanning circuit according to the invention shown input resistance through the input resistance represents. The connections of this circuit are enlarged by 30 31 to convert into an analog signal stream as with the known analog signal circuit converts. During the times between the successive ones of Fig. 1 and are accordingly also with the other following sampling pulses ν 12 (Fig. 3b) flows the same reference numerals. The analog is the analog current from transistor 32 via the Tran voltage signal ν 11 is applied to input 11. sistor 35 to earth. The transistor 35 is conductive, there This signal is sampled when a sampling 35 its base potential is lower than the base potential pulse voltage ν 12 is applied to input 12. of the third transistor 36 is. When a sampling pulse The ν 12 sampled at the individual sampling times is applied to the input 12, the flows The value is stored in a storage capacitor 13. Analog signal current through the third transistor 36 chert until the charge at the end of the storage time to the capacitor 13. The transistor 36 is to this by an erase pulse ν 12, which is conductive via the input 40 instant, since the base potential of the second 14 is applied, is discharged. The sampled off transistor is higher than the base potential of the third output voltage ν 15 is applied to the output 15 of the transistor. As mentioned before, will placed. Similar to the known scanning circuit, the erase pulses ν 14 (FIG. 3 c) at input 14 according to FIG. 1, this circuit contains a row applied at the end of each storage interval to the circuit between earth and the ungrounded 45 capacitor 13, whose voltage is the Connection of the capacitor 13 (that is, as shown, the sampled output voltage ν 15 represents. This represents, the connection of the capacitor 13, to which the output voltage, which is present at the output 15, is in Analog voltage ν 11 is applied). F i g. 3 d shown.

This series circuit contains the quenching transistor If now the sampled output voltage ν 15

22, which is controlled by the erase pulses ν 14, 50 has dropped to zero after an erase pulse ν 14,

and a current limiting resistor 23. A sampling pulse ν 12 is applied to the input 12 for

The erase transistor 22 is preferably applied in this way to the duration of the sampling time t _s . When the concluded that an electrode is connected to earth. Corresponding to the duration t _{s of} the sampling pulse sufficiently small to the opposite of the polarity of the potential at the memory over the shortest period of the analog voltage capacitor 13, a 55 signal ν 11 is used here as the erasing transistor 22 (as is common practice), then a transistor of the PNP type is used . the third transistor 36 acts as a constant current results when the size of the analog signal transistor 32, which is connected to the input resistor 31 60 current at one of the sampling times ti, t2, t3 and the supplied analog signal etc. equals i _s and the capacitance of the storage capacitor ν 11 in one Analog signal current transforms sator 13 is equal to C , serves as a voltage across the storage and as an analog signal current source, whose current cherkondensator 13 or as a sampled output of the voltage ν 11 is proportional. For the trans-voltage ν 15:
sistor 32, a bias voltage source 33 is provided. 65 vl5 = (t / C) i
A second transistor35 is provided and so \ s) s
connected that the emitter receives the analog signal. From the formula it can be seen that this receives current from the first transistor 32. At the base voltage is proportional to the analog signal. the

Emitters of the pair of transistors 35 and 36 are connected to one another. One of these transistors, transistor 35, is controlled by the successive sampling pulses applied to the base, thereby causing the other transistor 36 to not deliver current to capacitor 13 during the times between the sampling pulses and during the sampling pulses as Constant current source for the capacitor 13 is used. This constant current is proportional to the analog signal that is present at input 11 at sampling times ti, ti, t3, etc. In this combination, the transistors 35 and 36 operate as sampling switches of the type of a current changeover switch in order to allow the current to flow from the first transistor 32 via the one transistor 35 to earth and via the other transistor 36 to the storage capacitor 13.

When the analog signal takes both positive and negative values, then it becomes a bias circuit 38 for the emitter of transistor 32 is required to generate the necessary bias current for the Get emitter. This circuit consists of a series connection of a resistor and a Voltage source, as shown in FIG. 2 is represented by dashed lines. If the analog signal is both can assume positive as well as negative values and also has no direct current component, then it is expedient, additionally between the input 11 and the resistor 31 a direct current blocking Use capacitor 39, which is also shown in dashed lines in FIG. if the analog signal is an analog current signal, then the analog signal input 11 can directly with the Emitters of the second and third transistors 35 and 36 are connected, i. i.e., you can at first Forego transistor 32.

So far it has been assumed that the signals which are present at the analog signal input 11 are analog signals are. However, the signals to be sampled need not necessarily be analog signals. It is only necessary that a signal is present which has finite values at least at the sampling points.

In FIG. 4 shows a further possible embodiment which is essentially the same Structure like that in FIG. 2 has the arrangement shown, with the exception that the transistor 35 of the transistor pair 35 and 36, which together constitute the sampling switch, is arranged so that it is above his Collector emits a constant current to the storage capacitor 13, which is proportional to the analog signal to each of the sample points. The other deviation from the circuit according to FIG. 2 exists in that the collector electrode of the third transistor 36 is grounded.

The mode of operation of the arrangement according to FIG. 4 is now used in conjunction with the waveforms of FIG. 5 explained. The F i g. 5 corresponds substantially to the F ig 3 with the exception that, for the strobe voltage ν 12 ti to the sampling points, ti, t3 and so on, a voltage is selected, which is lower than the bias voltage El is applied to the base of the transistor 36 of the voltage source 37 is created. Between two successive sampling pulses, the base of the second transistor 35 is at a higher potential than the base of the third transistor 36. It follows that the third transistor 36 is conductive and the analog signal current flows to ground. When a sampling pulse ν 12 is applied to the input, the base of the second transistor 35 assumes a potential which is lower than the potential at the base of the third transistor 36, so that the second transistor 35 becomes conductive and then the analog signal current to the storage capacitor 13 transmits. It can be seen from this that the arrangement according to FIG. 4 operates in a similar way to the arrangement according to FIG. 2.

Claims (3)

Patent claims: 1. Circuit arrangement for pulse-shaped sampling of alternating current signals, in which the signal values sampled by means of a semiconductor switch controlled by a sampling signal are stored in a capacitor and the capacitor can be discharged by a clear signal, in particular for channel distributors for the PCM, characterized in that two semiconductor switches Transistors (35, 36) are used to which the signal to be scanned (vll, Q is applied, and that these transistors alternately block and switch on depending on the sampling signal (vl2) and that the capacitor is charged via the one switched transistor (36) and the input signal is short-circuited via the other transistor (35) which is switched through. 2. Circuit arrangement according to claim 1, characterized in that signals (vll) present as voltage are converted in a transistor stage (32) into a corresponding current (i _s ) . 3. Circuit arrangement according to claim 1, characterized in that the bias voltage (E 2) applied to the base of one transistor (36) has a value between the pulse voltage (E) and the voltage in the pulse pauses at the base of the other transistor (35), this other transistor being controlled by sampling pulses applied to the base. Considered publications:
German Patent No. 812441. 1 sheet of drawings 609 667/363 9.66 © Bundesdruckerei Berlin