NO166350B - ELECTRONIC RECORDING UNIT FOR INFORMATION TECHNICAL DEVICES. - Google Patents

Description

The invention relates to an electronic voting unit

for information technology devices, in particular television and broadcast receiver devices, where a PLL system is used which, when tuning the receiver device, adjusts the individual tuning circuits to optimal values in turn and assigns the derived tuning values to the individual filter circuits.

In DE-OS 28 54 852, for example, such a tuning unit is described which, with the help of three auxiliary oscillators and analog stores assigned to these, and using the PLL coupling, tunes the high-frequency circuits to the desired reception frequency. In the case of this tuning unit, the tuner oscillator is also drawn in during the adaptation. In addition, auxiliary oscillators corresponding to the number of high-frequency circuits to be adapted are needed. The number of necessary auxiliary oscillators and thus the material cost increases to a particular extent, e.g. when when adapting a television receiver band I, band III and bands IV and V are to be adapted. In this connection there is a risk of ambiguities between the frequencies from the tuner oscillator and from the auxiliary oscillators and the reception frequencies. For a practical realization of the proposed tuning unit, it is unfortunate that the auxiliary oscillators' magnetization windings with the individual coils in the high-frequency circuits can induce unintended resonances and damping of the circuits, which also leads to an uncontrollable pretuning when the auxiliary oscillators are disconnected after the adaptation has taken place. In addition, there are arranged analogue stores which must be left at chronological intervals in order for the optimal tuning values to be achieved. For these reasons, it is in principle not possible to achieve an optimal adaptation of the receiving device. In addition, the constantly repeated reverberation conditions visible or audible disturbances on the picture screen or in the loudspeaker.

In the magazine "Nachrichten elektronik" issue 11/79, pages 365-368, there is described a tuning method for broadcast receivers where additional auxiliary circuits are also used in the high-frequency filters. Here, too, adverse influences on the circuits are obtained during operation of the adapted receiver. As indicated on page 367, left and middle columns, the accuracy of the tunings using special components is only achieved in the form of exactly paired diodes. This also requires a not inconsiderable expense.

Finally, a self-tuning tuner is known from US-PS No. 4,334,323 where the antenna signal must be separated from the tuner input during tuning. During tuning, this tuner uses 2 auxiliary oscillators, which gives rise to inaccuracies due to modulation products.

The invention is based on the task of achieving a

automatic self-adjustment of information receiver devices without the use of selected components, and with the aim of obtaining maximum amplitude and optimal selection in all reception areas without interfering with the HF receiving unit. This task will be

solved with measures specified in the patent claims.

In the following, the essential aspects of the invention will be illustrated by an embodiment with reference to the drawing. Fig. 1 shows a block connection diagram for the voting unit according to the application.

Fig. 2 shows the frequency pass curve for a receiver

to illustrate the operation of the device in fig. 1.

Fig. 3 shows the tuning voltage limit for the different circuits. 1 denotes a high-frequency part of an information receiver device, E.g. a television receiver. The receiving signal is supplied to a receiving part via an antenna 2, selected by means of the high-frequency circuits 3, 4, 5 and amplified by amplifiers 6, 7. In a mixer 8, the intermediate frequency signal is produced, which occurs by superposition with a frequency provided from the oscillator 9. The oscillator 9 becomes set with regard to frequency by means of a PLL link consisting of the frequency divider 10, which is connected to the oscillator 9, and the phase compensator 11, which is supplied with a stable reference frequency produced by a quartz crystal 12. The different oscillator frequencies occur by changing the division factor for the programmed frequency divider 10 which is controlled by a microprocessor 13 via the data line 14.

The automatic adaptation of the receiving device takes place

as follows:

With each new channel selection, which is likewise controlled via the microprocessor 13, the receiver oscillator 9 is disconnected, and instead a single additional oscillator 15 which alone covers the overall reception frequency range is set to at least two frequencies which can be switched, and which characterize the desired HF pass curve , and wood. with the help of the applied PLL

link 10, 11, 12 connected to the receiving link's antenna input during stable oscillation. Now, starting with circuit 3 and ending with the last circuit 5, adaptation to an optimal output voltage behind the last stage is carried out in turn. With a view to symmetrical adaptation, the additional oscillator becomes 15 i

that connection under control from the microprocessor 13 via the data line each time switched alternately to at least two frequencies, which are however dependent on the selected reception channel. Via a detector link 16, the result is conveyed to the microprocessor 13 after it has been, by means of an analogue-digital converter 17

has been reshaped accordingly. The tuning voltage is individually continuously changed and led by the microprocessor 13 to the individual circuits via digital-to-analogue converters 13, 19, 20 until the determined output criterion is present at the analogue-to-digital converter 17. With the digital-to-analogue converters, it is a matter of static , monotone converters, i.e. that after the introduction of data they are separated from the microprocessor 13 in order to avoid device disturbances, and retain the digital word either until tuning is done on another channel, or until a fine-tuning occurs. This automatic vote takes place with each new one

channel setting. Adaptations of the circuits during the manufacture of the receiving apparatus can thus be dispensed with. In the case of a simplified device, the additional oscillator can be set to only a single frequency of the selected reception channel, so that the optimal adaptation only takes place to this frequency. In the case of band-pass filters with two or more circuits, the capacitance diodes in the circuit which are not currently participating in the adaptation must be connected by means of a forward voltage.

When receiving an offset channel or in the case of search information, the data word is changed step by step for the individual digital-to-analogue converters.

In fig. 2, frequency-dependent pass curves are plotted which, depending on the reception frequency within a band, exhibit different characteristics. Thus, L/C ratio and diode efficiency are poor at low frequencies within a band. Here the additional oscillator 15 is set to only 6n frequency fO. At medium frequencies within the band, the additional oscillator is alternately switched to two frequencies f^ and f2 which lie symmetrically about a center frequency at a distance of 1-2 MHZ.

At high frequencies in a band, L/C ratio and diode efficiency are good, and the additional oscillator is alternately switched to two frequencies f3 and f4 which correspond to the hump frequencies of the pass curve. In fig. 3, the limits for the tuning voltage ranges are drawn. It has proven appropriate to achieve a maximum possible HF selection that the upper and lower limits for the tuning voltage for the oscillator circuits are lower than those for the HF filter circuits, e.g. the tuning voltage for the VHF range is between 2 and 25 V (a) for the oscillator circuit and between 3 and 30 V (b) for the filter circuits, as shown in fig. 3.

Claims (7)

1. Electronic tuning unit for information technology devices, in particular television and broadcast receiver devices where a PLL system is used which, when tuning the receiving device, in turn adapts the individual tuning circuits to optimal values and assigns the derived tuning values to the individual filter circuits, characterized in that the tuner oscillator ( 9) each time when selecting a desired reception channel is disconnected and in return a single oscillator (15) can be connected to the antenna input of the tuning unit (1) (tuner) which alone sweeps over the overall reception frequency band and simulates the reception signals, during which the additional oscillator (15) at high frequencies can alternately be switched to at least two frequencies, and at low frequencies to one frequency, and that a device (16) is arranged which demodulates the respective HF signal, and whose output voltage via an A/D converter (17 ) is supplied to a microprocessor (13) which, when a maximum and symmetry is determined ical output curve in the HF signal via D/A converters (18,19,20) delivers the value of the tuning voltage for the capacitance diodes located in the individual tuning circuits (3,4,5) . 2. Tuning unit as specified in claim 1, characterized in that the capacitance diodes in the circuits which, in the case of bandpass filters with two or more circuits, do not currently participate in the adaptation process, can receive a switching voltage in the forward direction as a bias voltage. 3. Tuning unit as specified in claim 1, characterized in that the adaptation of the HF circuits (3,4,5) by means of the additional oscillator (15) is carried out at only a single frequency per reception channel. 4. Tuning unit as stated in claim 1, characterized in that the PLL link (10-12) as well as the D/A converters (18-20) are disconnected from the microprocessor (13) after the adaptation process. 5. Tuning unit as specified in claim 1, characterized in that for reception of an offset channel or during a search operation, an incremental change of the derived data word for the individual D/A converters and for the tuner oscillator can be performed. 6. Tuning unit as stated in claim 1, characterized in that the additional oscillator (15) is controlled by the tuner component already present in the PLL link (10-12). 7. Tuning unit as stated in claim 1, characterized in that the tuning range for the oscillator is lower than for the HF filters to provide the maximum possible HF selection.