DE1122101B - Electronic information storage - Google Patents

Description

Electronic information storage Addition to patent 1059 508 The main patent 1059 508 relates to electronic information storage for storage of any length of information given briefly about a certain state variable. The storage takes place with the aid of a pulse or sine generator, which supplies vibrations according to a periodic time function characteristic of the information and is synchronized with a pulse sequence causing an electronic latching of the periodic time function that is set in each case. Time functions characteristic of the information are, for example, the duty cycle of a pulse generator or the frequency of a pulse or sine generator.

In a further development of the electronic information memory according to the The main patent is the present additional invention that the information supplied the phase position of the generator oscillations compared to the oscillations of a second, the synchronizing pulse train supplying generator influences and that this The phase position is maintained by the electronic detent and in a phase discriminator converted into a voltage that can be removed at any time and corresponds to the information will.

According to a preferred embodiment of the additional invention, the oscillation frequencies of both generators are the same. In this case as well as in the case of unequal oscillation frequencies, the synchronizing pulse sequence can be obtained by multiplying the oscillations supplied by the second generator. In the case of unequal oscillation frequencies, the frequency of the second generator is expediently a multiple of the frequency of the first, the so-called memory generator. In such a circuit, the frequency of the memory generator is multiplied before it is fed to the phase discriminator. The memory generator can be synchronized with the pulse sequence directly or indirectly, for example via a discriminator and a reactance circuit. When several information memories are interconnected to form a multi-digit memory group, only one common generator generating the synchronization frequency and only one multiplier stage is required. If the electronic information memory is used for remote control purposes or as a deflection generator in a television receiver, the synchronizing pulse sequence can be derived from the received synchronization signal. The amplitude filter separating these pulses from the rest of the image signal assumes the function of the second generator. The invention and associated details are to be explained below with reference to the drawings. Fig. 1 shows a block diagram of the electronic information memory according to the additional invention. The output voltage of the second generator G2 , which is multiplied in frequency in a multiplier stage V, is fed to a storage generator Gl as a synchronization pulse sequence. If, for example, both generators G 1 and G 2 work at the same frequency, "the number of phase relationships between the two generator oscillations that can be stored as information corresponds to the multiplication factor of circuit V. This multiplies the frequency of generator G2, for example by generating and filtering out corresponding harmonics to n -fold. we obtain n storable information values. the respective phase angle between the oscillations of the generator G2 and generator of the memory G 1 is detachable in a phase discriminator D in a any time of the converted information corresponding voltage.

The diagrams of FIGS. 2 a to 2 c are intended to illustrate the mode of operation of the new information memory. 2a shows the time profile of the voltage ii, = f ("-)" t) at the output of the generator G2 supplying the synchronizing pulse sequence. As already mentioned, this can also be, for example, the synchronous pulses of a television signal separated from the image signal or of another signal provided with periodically recurring control or synchronous pulses, as is often found in telecontrol and measurement technology. The output voltage u2 of the generator G2 is, for example, distorted in the multiplier Y and the desired nth harmonic is filtered out and amplified. . At the output of the multiplier V then a voltage shown in Figure 2b is uv 1 (n - w, t), where n is an integer and in Fig 2b n 6 is selected.. This results in six different stages of the mutually lockable phase position between the oscillations of the storage generator Gl and those of the second generator G2. Depending on which of the oscillation trains of the voltage uv is used for synchronization within a period of the storage generator G 1 , there is a corresponding phase difference T i between the two generator oscillations. If one assumes the absolute phase position of the voltage of the generator G 2 to be zero, i. H. u 2 = f (a) 2 01 this results in ul = f 41 t + 991) 5 for the output voltage of the storage generator where o-) l = f «» 2) 'Stl Z- B- (»l = 0) 2 (see. Fig. 2 c). The phase difference q), u is the phase discriminator D to a voltage. = 1 (99 n ") nüt r = 1, 2, .., converted integer that is at any time be tapped off as stored information. According to the respectively synchronized phase position 99r between the two vibration generator occurs at the control voltage output of a voltage u .. Phasendiskrinünators D as shown schematically in Fig. 3.

As a result of the synchronization of the storage generator G 1 with the oscillations derived from the generator G 2, the relative phase position cannot exceed the range between two synchronization stages defined by the electronic detent, even if the frequency changes due to heating of the frequency-determining circuit parts or if the operating voltage fluctuates. The memory generator Gl will always be synchronized to the same oscillation train of the synchronization pulse train.

The desired phase jump from one item of storage information to another can be triggered by a correspondingly metered phase or frequency jump of the storage generator G 1 or of the generator G 2. You can usually do this by a corresponding voltage jump, z. B. cause on the control electrodes of the vibration generator. A further development of the additional invention consists in that the generator G2 is synchronized indirectly via a special phase discriminator. The multiplier V can also be moved to the output of the memory generator G 1 .

Claims (2)

PATENT CLAIMS: 1. Electronic information memory for storage of any length of information given briefly about a certain state variable with the help of a pulse or sine generator, which supplies oscillations according to a periodic time function characteristic of the information and with an electronic latching of the periodic time function that occurs in each case Pulse sequence is synchronized, according to patent 1059 508, characterized in that the information supplied influences the phase position of the generator oscillations in relation to the vibrations of a second generator delivering the synchronizing pulse train and that this phase position is maintained by the electronic detent and converted into a phase discriminator that can be removed at any time. voltage corresponding to the information is transferred. 2. Information memory according to claim 1, characterized in that the oscillation frequencies of both generators are the same. 3. Information memory according to claim 1 or 2, characterized in that the synchronizing pulse train is obtained by multiplying the vibrations supplied by the second generator. 4. Information memory according to claim 1, characterized in that the frequency of the second generator is a multiple of the frequency of the memory generator. 5. Information memory according to claim 3 or 4, characterized in that the frequency of the memory generator is multiplied before being fed to the phase discriminator. 6. Information memory according to one of claims 1 to 5, characterized in that the memory generator is synchronized directly with the pulse train. 7. Information memory according to one of claims 1 to 5, characterized in that the synchronization of the memory generator with the pulse train takes place indirectly via a discriminator and a reactance circuit. 8. Information memory according to one of claims 1 to 7, characterized in that when several information memories are interconnected to form a multi-digit memory group, a common generator generating the synchronization pulse sequence is provided. 9. Information memory according to one of claims 1 to 8, characterized in that a common multiplier stage is provided when several information memories are interconnected to form a multi-digit memory group.