DE2834231A1 - Synchronisation of oscillator with input circuit of superhet receiver - sorting control voltages for input circuit corresp. to those of oscillator - Google Patents

Abstract

The circuits automatically synchronised have electronic tuning controlled by a variable control voltage. The oscilator's control voltage range is divided into discrete stops. When at least the same number of control voltage steps is applied to the oscillator, a control voltage is applied to the input circuits so that its resonant frequency is lower by the i.f. than the oscillator frequency. Voltage values so determined for the input circuit are reproducibly stored without change. Application to the oscillator of control voltages retrieves from the store corresponding input circuit voltages and applies them to it.

Description

The invention relates to a method for automatic synchronization adjustment

between the oscillator and the pre-circuit in a heterodyne receiver (superhetl, both of which can be controlled by means of a variable control voltage ttel have.

With this type of tuning of the heterodyne receiver by means of ele1 <tronic The means of coordination is to achieve synchronization between the pre-circle and the one around the Intermediate frequency offset oscillator circuit quite problematic.

Since both the oscillator and the pre-circuit are usually connected to the same. The tuning voltage or current can be controlled, synchronism can be achieved.

between oscillator and pre-circuit only through an iterative adjustment of the non-tunable, i.e. not controlled during tuning, circular elements Wim Oscillator and pre-circuit can be achieved. This comparison is not only very difficult and the circuitry is very complex, but has the main disadvantage that it refers to a maximum of two and a maximum of three points, the so-called slip points and not across the entire frequency range. Outside of these adjustment points you can considerable equal or parallel running errors occur.

The - invention is therefore based on the object of a method for automatic synchronization setting between oscillator and pre-circuit of the input to show that there is an exact synchronization between the pre-circuit and the oscillator across the entire frequency range, i.e. the entire tuning range.

According to the invention, this object is in a method of the opening paragraph mentioned type solved by the fact that the control voltage range for the oscillator divided into a variety of discrete control voltage values that one at least to an equal number of consecutive discrete control voltage values defines such a control voltage value for the pre-circuit, at which the resonance frequency of the pre-circuit is lower than the intermediate frequency by the with these discrete control voltage values adjustable for the oscillator Oscillator frequency that the control voltage values determined in this way for the pre-circuit Inevitably and reproducibly stores and that one with the oscillator supplied control voltage values the associated control voltage values for the pre-circuit retrieves and at the same time feeds this to the pre-circuit.

With this method, the entire frequency range or Tuning range a-good synchronization of pre-circuit and oscillator achieved. For Sufficient sensitivity of the heterodyne receiver is required the jump in the control voltage from a discrete control voltage value to the to make others as small as possible for the oscillator. This means that the control voltage range for the oscillator very fine into a multitude of discrete control voltage values must be divided. Since the bandwidth of the pre-circle is much larger than the bandwidth of the intermediate frequency filter is sufficient for good synchronization of Oscillator and pre-circuit, if one has an equal number of consecutive discrete control voltage values for the oscillator a single control voltage value for the pre-circuit, at which the resonance frequency of the pre-circuit around the Intermediate frequency is lower than the oscillator frequency. For such a group of successive discrete control voltage values is then only one assigned control voltage value for the pre-circuit is available, each with a the control voltage values are called up from the respective group and fed to the pre-circuit will. With this method, the oscillator and pre-circuit must run in good synchronicity relatively few control voltage values are stored for the pre-circuit, which is the Allows use of small memories.

In a further development of the method according to the invention, everyone is individual control voltage value for the oscillator such a control voltage value assigned for the pre-circuit, in which the resonance frequency of the pre-circuit is exactly is lower by the intermediate frequency than that with the control voltage value for the Oscillator adjustable oscillator frequency.

With this method, it is true that this results over the entire frequency range an absolutely exact synchronization of the oscillator and pre-circuit, but one must be here considerably larger number of control voltage values stored for the pre-circuit which increases the memory required and thus makes it more expensive.

In the method according to the invention, the additional capacitors are unnecessary, which have hitherto usually been used to narrow the variation in oscillators, their electronic tuning means are designed as capacitance diodes.

In the case of very good synchronization, the inventive Procedure a much simplified comparison. The required circuitry Effort is low, especially if you use this procedure at a local recipient with digital search and digital transmitter storage, as this is where the control voltage values for the oscillator are already digitized and as discrete control voltage values are present.

In the circuit arrangement for implementing the invention Procedure for a heterodyne receiver with digital search and station memory, which has digital storage and control circuitry is digital Program memory provided, its memory locations (addresses) each with one the control voltage values for the pre-circuit are occupied, its address inputs the digital storage and control circuit are connected such that the Control voltage values for the oscillator are the permanently assigned address of the Query the program memory and its data outputs via a digital-to-analog converter are connected to the pre-circle.

In a preferred embodiment of the circuit arrangement, it is digital Program memory designed as a mask-programmed read-only memory (ROM).

With such a program memory, the inventive Manufacture circuit arrangement relatively inexpensive.

In a further embodiment of the circuit arrangement is the Digital-to-analog converter is supplied with an offset voltage. Because of this offset voltage can Manufacturing and component tolerances are compensated.

The method according to the invention for automatic synchronization adjustment between pre-circuit and main oscillator and the circuitry for implementation this method is shown schematically below with reference to one in the drawing Embodiment of the circuit arrangement described in more detail.

From the superimposition receiver (superhet) is only in the drawing schematically, the antenna 10, the pre-circuit 11, the mixer or the mixer 12 and the oscillator 13 indicated. Pre-circuit 11 and oscillator 13 have electronic Tuning means, which are designed as capacitance diodes 14 and 15 here. By Supply of control voltages to the pre-circuit 11 or to the oscillator 13 can be the capacitance value of these capacitance diodes 14, 15 change and pre-circuit and Tune the oscillator.

The superimposition receiver shown schematically in the drawing is equipped with a digital search and a digital station memory.

For this purpose, a memory and control circuit 16 is provided, the Outputs via a digital-to-analog converter 17 to the control voltage input of the Oscillator 13 are connected. The memory and control circuit 16, which is usually is designed as an integrated circuit (IC) is in connection with the digital-to-analog converter 17 available as a commercially available search run and storage system in the form of a 1C set 18. This IC set 18 is indicated schematically in the drawing by dash-dotted lines.

In the method according to the invention, the control voltage range is now subdivided for the oscillator 13 into a plurality of discrete control voltage values. Turns one this method in the heterodyne receiver shown schematically in the drawing with digital search and digital station storage, these are discrete Control voltage values already exist and you only need them from the memory and Control circuit 16 to remove.

To at least an equal number of consecutive discrete control voltage values for the oscillator 1-3 are set one each Control voltage value for the pre-circuit 11, at which the resonance frequency of the Pre-circuit 11 is lower by the intermediate frequency than that with these control voltage values for the oscillator 13 adjustable oscillator frequency. The voltage values determined in this way for the pre-circuit 11 is stored unchangeably and reproducibly. With each the control voltage values supplied to the oscillator 13 are now called up Control voltage values for the pre-circuit '11 and leads them to the pre-circuit at the same time 11 to. The control voltage values to be defined for the pre-circuit can easily be determined determine by synchronism tests. An ideal synchronization of pre-circuit 11 and oscillator 13 over the entire frequency range can be achieved if you look at each individual of the discrete control voltage values for the oscillator 13 each have such a control voltage value for the pre-circuit 11, at which the resonance frequency of the pre-circuit 11 is exactly the intermediate frequency lower than that with the voltage value for the Oscillator 13 adjustable oscillator frequency. Because of the sensitivity of the The subdivision of the control voltage range for the oscillator via agerungsempfänger 13 can be made very finely in very small discrete control voltage values this would mean that one has an equally large number of discrete control voltage values for the pre-circuit 11 would have to save. The memory required for this would be right great. Since the bandwidth of the pre-circuit (approx. 20 kHz) is much larger than the bandwidth of the intermediate frequency filter (approx. 5 kHz) can be the frequency grid, and so that the gradation of the control voltage values for the pre-circuit 11 is coarser than the frequency grid, and thus the gradation of the control voltage value.e, for.the oscillator. For a very good synchronization, it is sufficient if you proceed as described above an equal number of consecutive discrete control voltage values for the oscillator 13 is combined into a group and one such group assigns such a control voltage value for the pre-circuit 11 at which the resonance frequency of the pre-circuit 11 is lower by the intermediate frequency as the with the control voltage values of this group for the oscillator adjustable average Oscillator frequency. The number of storage spaces required is therefore essential lower and the circuitry; cal Au; -. vond to carry out the process smaller. The assignment of the control voltage values for the pre-circuit and the oscillator is fixed, unambiguous and unchangeable.

In the circuit arrangement shown schematically in the drawing for a heterodyne receiver with digital search and digital station storage is a digital program memory for carrying out the method described above 19 provided. The storage spaces (addresses) of the program memory 19 are each assigned one of the control voltage values for the pre-circuit 11. Preferably is this program memory 19 is designed as a mask-programmed read-only memory (ROM). The control voltage values, once defined, are in such a read-only memory Permanently programmed unchangeable and accessible at any time.

The address inputs of the program memory 19 are via an address bus (Bus) 20 connected to the digital storage and control circuit 16 in such a way that that the control voltage values for the oscillator 13 are permanently assigned Query the addresses of the program memory 19. If one assigns, as described above, each an equal number of discrete control voltage values for the oscillator 13 to a single control voltage value for the pre-circuit 11, so summarizes this number of successive discrete control voltage values for the oscillator 13 a group with a single assigned control voltage value for the pre-circuit 11 together, only one control voltage value of this group asks, for example the first, the addresses of the program memory 19 from. No need for addressing then the low-order bits.

The data outputs of the program memory 19 are via a data bus (Bus) 21 connected to the input of a digital-to-analog converter 22.

The control input is then at the output of the digital-to-analog converter 22 of the pre-circuit 11 connected.

For the purpose of fine adjustment and compensation of the manufacturing and Bouteiletoleranzen the circuit is the digital-to-analog converter 22 a. Offset voltage fed.

If the oscillator 13 is now tuned through, the pre-circuit 11 the control voltage values specified in the program memory 19 are correct Sequence retrieved and fed to the pre-circuit 1 i. Vibrates in every tuning phase so that the pre-circuit 11 is exactly lower than the oscillator by the intermediate frequency 13th

Claims (5)

Method for automatic synchronization adjustment between oscillator and pre-circuit in a heterodyne receiver (superhet), the both electronic tuning means controllable by means of a variable control voltage have, characterized in that the control voltage range for the oscillator (13) divided into a variety of discrete control voltage values that one at least for the same number of consecutive discrete control voltage values For the oscillator (13) such a control voltage value for the pre-circuit (11) defines at which the resonance frequency of the pre-circuit (11) is around the intermediate frequency is lower than that with this discrete control voltage. voltage values for the oscillator (13) adjustable oscillator frequency, that the voltage values determined in this way for the pre-circuit (1 1) cannot be changed and reproducibly stores and that each with the oscillator (13) supplied Control voltage values the associated control voltage values for the pre-circuit ( 11) and at the same time feeds it to the pre-circuit (11). 2. The method according to claim 1, characterized in that each individual discrete control voltage value for the oscillator (13) such Assigns control voltage value for the pre-circuit (11) at which the resonance frequency of the pre-circuit (11) is exactly lower by the intermediate frequency than that with this Control voltage value for the oscillator (13) adjustable oscillator frequency. 3. Circuit arrangement for performing the method according to claim 1 or 2 for a heterodyne receiver with digital search and digital Station memory comprising digital storage and control circuitry, characterized by a digital program memory (19), its memory locations (Addresses) each assigned one of the control voltage values for the pre-circuit (11} whose address inputs are connected to the digital storage and control circuit (16 ) are connected in such a way that the control voltage values for the oscillator (1 3) query the permanently assigned addresses of the program memory (19), and its data outputs via a digital-to-analog converter (22) with the pre-circuit (11) are connected. 4. Circuit arrangement still claim 3, characterized in that the digital program memory (19) as a mask-programmed read-only memory ( ROM) is formed. 5. Circuit arrangement according to claim 3 or 4, characterized in that that the digital-to-analog converter (22) is supplied with an offset voltage.