DE2746931A1 - TELEVISION RECEIVER TUNING DEVICE - Google Patents

Description

The invention relates to a device for tuning a television receiver and, more particularly, to circuitry for selecting the desired television channel and for converting the received signal from the frequency of the selected channel to the fixed frequency at which the signal amplifier circuits operate. This voting and conversion circuitry is commonly known as a "tuner" or "tuning". There are many different types of tuning available, all of which, even if they differ in the circuit arrangement, have one thing in common: they are very complicated, especially with regard to component assembly and the adjustment of the finished circuit.

Another feature common to known types of tuning is that they offer very little versatility and vary widely in performance.

In fact, there is such a wide range of tuners available that they can be classified, for example, according to the television channels they are designed to receive. With such a classification, it should be noted that there are tuners for receiving channels on the VHF + UHF bands or only UHF or CATV bands or combinations of CATV + VHF or CATV + VHF + UHF bands. Obviously, the tuners in each group differ considerably in terms of their design.

However, such a wide range of tuners is inevitable, considering that the same television set must be distributed in countries broadcasting on different bands.

For example, in the UK it is sufficient for the tuner to receive the signals broadcast on the UHF band, while in Italy it must also be designed to receive VHF band signals, and in some countries such as Belgium where cable television is large CATV tape signals have found widespread use.

In view of the complexity of the device and the difficulties encountered, both in terms of manufacture and construction, it has not previously been found possible to produce a single tuner which is both economical and satisfies all requirements.

The invention is therefore based on the object of providing a device for tuning with which these problems are overcome.

Another object of the invention is to create an inexpensive tuning device that performs well and is versatile.

Furthermore, according to the invention, a device for tuning is to be created which is designed for simple assembly of parts and trouble-free adjustment of the finished product.

To solve the problem underlying the invention, it is provided that a television receiver tuning device for receiving all television channels on the VHF, CATV and UHF bands and for converting the received signal to a lower frequency with an amplifier circuit for regulating the amplitude of the received signal and delivering the same to a first mixing circuit, an oscillator circuit of variable frequency for supplying the first mixing circuit is provided with a reference oscillation and a second mixing circuit which receives the signal coming from the first mixing circuit and a reference oscillation which comes from a second oscillator of fixed frequency, and is characterized by: that the received signals in the VHF band, in the CATV band and in the UMF band are converted by the first mixing circuit into a first intermediate frequency f [low] 1, which is on a frequency band lower and adjacent to the UHF television band, and that the second mixing circuit converts the signal from the first intermediate frequency f [low] 1 to a second intermediate frequency f [low] 2, which is lower than the frequency of the first television channel that belongs to the VHF band.

The invention is explained in more detail below using an exemplary embodiment with reference to the drawings. In the drawings are:

Fig. 1 is a block diagram of a possible arrangement of a vote according to the invention,

Fig. 2 is a circuit arrangement of the blocks shown in Fig. 1;

Fig. 3 shows the block diagram of a possible variant of the tuner shown in Fig. 1 and

FIG. 4 shows the circuit arrangement of the blocks shown in FIG.

In Fig. 1, 1 denotes an antenna which is connected to the input of a signal-translating circuit 2, a connection 3 being provided for regulating the signal attenuation. The output of the circuit 2 is connected to the input of three high-frequency amplifiers 4, 5 and 6 of different bandwidths. The amplifier 4 has, for example, a bandwidth that goes from 470 MHz to 900 MHz and is only suitable for amplifying signals in the UHF band. Of the

Amplifier 5 has a bandwidth that goes from 47 MHz to 139 MHz and is used to amplify signals on bands I and II and for CATV channels S [low] 1 to S [low] 5. The amplifier 6 finally has a bandwidth that goes from 139 MHz to 300 MHz and is used to amplify signals on the CATV channels S [low] 6 to S [low] 19 and on band III. All three amplifiers 4, 5 and 6 have traps in coordination for taking out unwanted frequency ranges within the above bands and a connection 7, 8 and 9 for switching the amplifier operation depending on the desired channel. The outputs of the amplifiers 4, 5 and 6 are connected to the input of a signal-translating circuit 10 having two connections 11 and 12 for regulating the attenuation introduced into the translated signal by the circuit. The output of the circuit 10 is connected to the first input of a mixing circuit 13 which has a second input which is connected to an oscillator 14 of variable frequency. The output of the mixing circuit 15 is connected to a first input of a mixing circuit 15 which also has a first output connection to which the received television signal is fed, converted into the fixed intermediate frequency with which the signal amplifier circuits that are connected downstream of the tuner operate. The mixer circuit 15 also has a second output terminal to which a control signal is fed to regulate the amplitude of the signal treated in the mixer circuit 15, and this is fed to the terminal 12 of the translating circuit 10 in order to prevent distortion or intermodulation caused by a excessive amplitude of the signal being treated is caused. Finally, an oscillating circuit 16 with a fixed frequency is connected to a second input of the mixing circuit 15.

The circuit works as follows:

The high frequency signal received by the antenna 1 is passed to the translating circuit 2, which can be a normal PIN diode damping circuit, and this receives the control signal that comes from the signal processing circuits that are connected to the downstream video detector. The function of this circuit is to prevent the amplifier stages that are connected downstream from becoming saturated in the event that very strong signals are received. Depending on whether the signal that is received belongs to one of the bandwidths of the amplifiers 4, 5 and 6, one of the amplifiers is activated by a signal that is received at one of the activation connections 7, 8 or 9 by the operator which selects the channel on the keyboard. If necessary, the received signal is also attenuated by the translating circuit 10.

When the control terminal 12 of the translating circuit 10 receives the signal from the mixer circuit 15, it operates an automatic gain control device within the tuner to provide better and faster amplitude checking of the signals which are processed within the tuner for additional protection against distortion and intermodulation beyond that provided by the automatic gain control device that acts on all receiver gain circuits between the antenna and the video detector.

The signal is then converted in the first mixer circuit 13 to a first intermediate frequency of 426 MHz and then in the second mixer circuit 15 to an intermediate frequency of 36 MHz, which is the normal frequency used in television receivers. In this way, a variably tuned band filter no longer needs to be provided at the input of the mixing circuit 13. Because the first intermediate frequency is 426 MHz, the frame rate that is generated during the conversion falls out of the receiving band and is automatically cut out.

No frame rate problems arise during the second conversion by the mixing circuit 15, which at one end receives the signal, which has been converted to the first intermediate frequency, and at the other end receives a reference oscillation of a fixed frequency (390 MHz) from the oscillator 16.

By sticking to a fixed frequency signal, the frame rate generated during the second conversion can easily be cut out by a highly selective fixed frequency filter. In this way only one variable frequency circuit operates, namely the oscillator 14, and a single varicap element can be used in place of the three used in known tuners.

Fig. 2 shows circuitry showing how the invention shown in block form in Fig. 1 can be put into practice. 19 denotes an input terminal which corresponds to the input terminal of the translating circuit 2 in FIG. The signal coming from the antenna goes through a capacitor 21 to a normal damping circuit consisting of three pin diodes 22, 23 and 24, then through a capacitor 25 provided at the output of the signal-translating circuit 2. The translating circuit 2 consists of five resistors 26, 27, 28, 29 and 30 and an inductor 34, which act as a bias and control network for the pin diodes, and four capacitors 31, 32, 33 and 36, which act as a bypass works. The translating circuit 2 also consists of a high-pass filter LC, which is formed from an inductor 20 and the capacitor 21, which together with the trap filter, which is composed of the inductor 35 and the capacitor 37, serves to set the correct bandwidth for the translator Supply circuit. The output of the latter is connected directly to the three input terminals of bandpass amplifiers 4, 5 and 6 shown in Fig. 1 which in Fig. 2 consist of transistors 38, 39 and 40 and associated parts.

Each of these transistors is in a common control electrode form (capacitors 41, 42 and 43 are shorts to the frequencies in question), and each has a resistor bias network made up of three resistors (44, 45, 46-47, 48, 49-50, 51, 52). Capacitors 53, 54 and 55 are also short circuits for the frequencies in question. With the input and the output of the three amplifiers, which consist of the three transistors 38, 39 and 40, are connected:

- A high-pass filter LC (56, 57, 58) at the input of the transistor 38;

- A high-pass filter LC (59, 60, 61, 62) at the output of the transistor 38;

- a band-pass filter LC (63, 64) at the input of the transistor 39;

- a band-pass filter LC (65, 66, 67, 68) at the output of the transistor 39;

- A band-pass filter LC (69, 70) at the input of the transistor 40;

- a band-pass filter LC (71, 72, 73, 74, 75) at the output of the transistor 40.

The outputs of the three amplifiers are therefore connected to the input of the signal converting circuit 10 shown in Fig. 1 and having a pin diode 76 which has a first control cycle coming through inductor 77 from the video detector and a second control signal through a resistor 78 receives. The translation circuit 10 also includes two filter capacitors 79 and 80 and a bias resistor 81. The translating circuit 10 sends the signal to the first mixing circuit 13, which consists of a transistor 82, connected in common control electrode form, which also receives the signal coming from the variable frequency oscillator, at the emission electrode through a capacitor 83. The mixing circuit has furthermore three bias resistors 84, 85 and 86, two filter capacitors 87 and 88, a high-pass output filter LC (89, 90) and a two-part tuned band-pass circuit which is tuned to the first intermediate frequency (426 MHz) and of capacitors 91, 94, 95 and 96 and two

There is resonance lines 92 and 93.

The variable frequency oscillator 14 shown in Fig. 1 consists of a transistor 97, bias resistors 98, 99 and 100 and filter capacitors 101, 102, 103 and 138. The oscillator circuit also has a positive feedback capacitance 104 and a varicap diode 105, which together with a Resonance line 106 fixes the frequency of the oscillator. The capacitance of the varicap diode 105, and hence the frequency of the oscillator 11, is regulated by a direct current bias voltage obtained from a + V voltage source through a resistor 107. The oscillation generated in the resonant circuit is then sent through a capacitor 108 and a resistor 109 to the first mixing circuit (mixing circuit 13 in FIG. 1).

The signal converted to the first intermediate frequency (426 MHz), which is made available at the output of the first mixing circuit, is then sent to the second mixing circuit (mixing circuit 15 in FIG. 1, which consists of a transistor 110, filter capacitors 111, 112, 113, 114 and bias resistors 115, 116, 117, 118.

The second mixing circuit also has two LC filters, which are formed from inductors 119 and 120 or capacitors 121 and 122. The former (119, 121) are tuned to the second intermediate frequency, i.e. 236 MHz (the normal intermediate frequency used in television receivers), and the latter (120, 122) are tuned to a forbidden frequency (e.g. the frequency of the Fixed oscillator 16). The collector of transistor 110 is connected to a diode 123, which detects the amplitude of the signal at the collector and, through the low-pass filter, which consists of a capacitor 124 and a resistor 125, generates a direct current signal to regulate the attenuation that is generated by the translating circuit 10 is introduced.

The converted signal is finally at the output terminal

126 is made available, from where the is sent to the IF amplifiers that are connected downstream in receivers.

The 390 MHz reference oscillation required for the second conversion is fed to transistor 110 through capacitors 127 and 128 by a fixed frequency oscillator (oscillator 16 in FIG. 1) consisting of transistor 129, filter capacitors 130 and 131 and Bias resistors 132, 133 and 134. The fixed frequency oscillator also has a feedback capacitor 135 and a resonance circuit, which is tuned to a frequency of 390 MHz, consisting of a capacitor 136 and a resonance line 137.

All of the circuits mentioned so far are powered by the terminals marked + B. In the case of the three bandpass amplifier circuits, the supply connection + B can also act as the activator connection, which is designated as 7, 8 or 9 in FIG.

With regard to the explanation of the mode of operation of the circuits shown in FIG. 2, reference is made to the explanation that was given in connection with the block diagram in FIG. The circuitry in FIG. 2 is enclosed by dashed lines to represent the corresponding blocks in FIG.

The television receiver tuner referred to in Figures 1 and 2, however, has one small drawback, from one point of view.

Because only one oscillating circuit of variable frequency is provided, which must be able to explore the entire frequency range from the smallest channel on the VHF band to the highest on the UHF band, the control signal applied to the oscillator must adjust the oscillation frequency change, can be changed within very small limits in order to give the user the opportunity to precisely tune the desired channel. For example, if the variable frequency oscillator consists of a voltage controlled oscillator, changes in the control voltage applied to the oscillator must be very small.

Because the control voltage is usually sent to a varicap diode that can withstand a voltage of 30V or less, changes in tuning that are noticeable to the user correspond to a change in the control voltage of a few MV. Apart from the supply line of such small voltage changes to a varicap diode, there is also the problem of noise interference in the control voltage and impairment of the tuning.

In all cases, even with the same control voltage change range, increasing the change range of the voltage controlled oscillator frequency makes the tuning process more critical.

The following description shows how the above problem can be overcome with a voting device.

201 in FIG. 3 denotes an antenna which is connected to the input of a signal translation circuit 202 which also has a connection 208 for checking the signal attenuation. The output of circuit 202 is connected to the input of three high frequency amplifiers 204, 205 and 206 having different bandpass characteristics. The amplifier 204, for example, has a pass band that goes from 470 to 900 MHz, i.e. it is only suitable for amplifying signals in the UHF band. The amplifier 205 has a pass band that goes from 47 to 139 MHz and is suitable for signals on bands I and II and for channels S [low] 1 to S [low] 5 on the CATV band. Finally, amplifier 206 has a pass band that goes from 139 to 300 MHz for signals on channels S [low] 6 through S [low] 19 on the CATV band and for television band III. The three amplifiers 204, 205 and 206 are also provided with traps that respond to unwanted frequencies at the The output of the three amplifiers 204, 205 and 206 are connected to the input of a signal-converting circuit 210, which has two connections (211 and 212) for regulating the attenuation introduced by the circuit in the translated signal. The output of the circuit 210 is connected to a first input of a mixer circuit 213 which also has a second input which is connected to an oscillator circuit 214 of variable frequency. The output of the mixer circuit 213 is connected to a first input of a mixer circuit 215, which also has a first output terminal at which the received television signal is made available, converted to the fixed intermediate frequency with which the Signal amplifier circuits that are connected downstream of the tuner work. The Mi Circuit 215 also has a second output terminal at which a control signal is made available, depending on the amplitude of the signal processed by mixer circuit 215, and this is sent to translation circuit 210 to prevent the processed signal from being amplified too high to cause distortion or intermodulation. An oscillator circuit 216 with a fixed frequency is in turn connected to a second input of the mixing circuit 215.

The oscillator circuit 214 consists of three oscillators of variable frequency in a voltage-controlled design, which are designated in FIG. 3 by 217, 218 and 219. Anyone can provide a continuous oscillation which is sent to the mixer circuit 213 as a reference signal. Furthermore, each has an activation connection 220, 221 and 222, each of which receives an activation signal for the oscillator. The three oscillators 217, 218 and 219 are activated according to the desired television channel. If it belongs to bands I or II or to channels S [deep] 1 to S [deep] 5 on the CATV band, the oscilloscope is lator 217 activated. If it belongs to band II or to channels S [low [6 to S [low] 19 on the CATV tape), the oscillator 218 is activated. Finally, if it belongs to the UHF band, the oscillator 219 is activated. All three oscillators 217, 218 and 219 have a connection (223, 224 and 225) to which the control voltage is fed, which determines the frequency of the signal which is generated by the voltage-controlled oscillator in question.

The circuit shown works as follows:

The high-frequency signal received by the antenna 20 is sent to the translator circuit 202, which can consist of a classic PIN diode damping circuit and which receives the control signal coming from the signal processing circuits associated with the downstream video detector. The function of this circuit is to prevent the downstream amplifier stages from becoming saturated when very strong signals are received. Depending on whether the signal to be received belongs to one of the three passbands of the three amplifiers 204, 205 and 206, one of the amplifiers is activated by a signal that goes to one of the activation connections 207, 208 or 209 that is sent from the keyboard through the User goes out when channel is selected. If necessary, the received signal is also attenuated by the translation circuit 210.

When control port 212 of translator circuit 210 receives the signal from mixer circuit 215, it operates automatic gain control within the tuner to provide a faster, more accurate amplitude check of the signal being processed in the tuner and to provide greater protection from distortion and intermodulation than provided by automatic gain controls that act on all receiver amplifier circuits between the antenna and the video detector.

The signal is then converted in the first mixing circuit 213 to a first intermediate frequency of 426 MHz, then in the second mixing circuit 215 to an intermediate frequency of 36 MHz, which is the normal frequency used in television receivers. In this way there is no longer any need to provide a variably tuned band filter at the input of the mixer circuit 213, because due to the fact that the first intermediate frequency is 426 MHz, the image frequency that is generated during the conversion is outside the reception band and is automatically cut out will. Regarding the second conversion carried out by the mixer 215, which at one end receives the signal converted to the first intermediate frequency and at the other end receives a fixed frequency (380 MHz) as a reference oscillation coming from the oscillator 16 there is no problem with the frame rate in this case.

By working with a signal of a fixed frequency, there is also no difficulty in cutting out the image frequency that is generated during the second conversion by means of a highly selective filter of a fixed frequency. The three voltage controlled oscillators 217, 218 and 219 are activated when the three amplifiers 205, 206 and 206 are activated respectively, i.e. when signals belonging to one of the following three bands are received:

- Volume I, Volume II, channels S [low] 1 - S [low] 5 of the CATV band

- Band III, channels S [low] 6 - S [low] 19 of the CATV band

- UHF band

With a first intermediate frequency of 426 MHz, the frequency ranges of the three oscillators 217, 218 and 219 are:

- Oscillator 217: 476 - 568 MHz

- Oscillator 218: 568 - 726 MHz

- Oscillator 219: 896 - 1278 MHz

As a result, there are no problems with the oscillators because the frequency ranges to be swept by each are small and because there is no need to change the control voltage of the voltage controlled oscillators by small amounts for no changes in tuning. This solves the critical coordination problems emanating from the device which have been described in connection with FIGS.

FIG. 4 shows a possible circuit arrangement of the oscillator 214 shown in FIG. 3.

The function of the three oscillators 217, 218 and 219 is performed by two transistors with associated passive circuits. A p-np transistor 226 performs the function of both the oscillator 217 and the oscillator 218 by switching a number of associated passive elements, while the function of the oscillator 219 is performed by a p-n-p transistor 227. The transistor 226 is grounded with its collector through an inductor 228, its emission electrode connected to the activation terminal 229 through a resistor 230 and its control electrode grounded through an RC unit, which consists of a resistor 231 and a capacitor 232, which are parallel- are switched. The control electrode is also connected to terminal 229 through a resistor 233, while terminal 229 is grounded through a capacitor 234.

The collector of transistor 226 is grounded through a capacitor 235 and a diode 236 connected in series. The series circuit comprising the resistor 237 and the capacitor 238 is connected in parallel with the diode 236. A second activation connection 239 is connected to the connection between the resistor 237 and the capacitor 238. A control terminal 240 is connected through the series of a resistor 241 to the cathode of a varicap diode 242, whose

Anode is connected to the collector of transistor 226. The emission electrode of the transistor 226 is connected to the cathode of the varicap diode 242 through a capacitor 243. The cathode of the varicap diode 242 and the control terminal 240 are grounded by two capacitors 263 and 244, respectively. The emission electrode of the transistor 227 is connected at one end to the activation terminal 245 through a resistor 246 and at the other end to ground through a capacitor 247. The control electrode is grounded by an RC unit consisting of a resistor 248 and a capacitor 249 and connected to the activation terminal 245 through a resistor 250. The activation connection 245 is in turn grounded through a capacitor 251. The collector of the transistor 227 is grounded through a resonance line 252 and connected to a second control terminal 253 through a varicap diode 254 and a resistor 255 which are connected in series.

In addition to the connection to the resistor 255, the cathode of the varicap diode 254 is connected at one end through the capacitor 256 to ground and at the other end to the emission electrode of the transistor 227 through a capacitor 257. Finally, the control terminal 253 is also grounded through a capacitor 258.

The circuit described works as follows:

The transistor 227, which is grounded in the basic form, as already described, forms the UHF oscillator. The frequency of the oscillator is determined by the resonance circuit, which consists of the line 252, the varicap diode 254 and the capacitor 256. The feedback required to support the oscillations is provided by capacitors 247 and 257. The function of resistors 246, 248 and 250 is to bias transistor 227, while resistor 255 is used to control the DC voltage that is applied to the control circuit. connection 253 is available to feed the varicap diode. The capacitors 249, 251 and 258 act as bypasses to short-circuit the signal to the oscillation frequency of the oscillator. The function of the activation terminal 245 is simply to activate or deactivate by supplying or cutting off the terminal voltage to transistor 227.

With regard to the operation of the resonant circuit, which consists of transistor 226, reference is made to the following: In its basic form, transistor 226 performs the functions of oscillator 218 according to FIG. 3 when the connection voltage for the transistor is present at activation connection 229 and no voltage is present at the activation port 239. In this way, the frequency of the generated oscillation is determined by the resonance circuit, which consists of the inductor 208, the varicap diode 242 and the capacitor 263. The oscillation is maintained due to the feedback of the capacitor 243. If the transistor 226 is to perform the function of the oscillator 217 according to FIG. 3, a direct current voltage is present at the activation terminal 239 in order to make the diode 236 conductive. In this way, the capacitor 235 is connected in parallel with the inductor 228 in order to shift the frequency range of the oscillator to the range of change required by the oscillator 217. The function of resistors 230, 231, and 233 is to bias transistor 226, while resistors 237 and 241 serve to provide the DC voltage required to operate diodes 236 and 242. The capacitors 232, 234 and 238 act as bypasses for the oscillator frequency signals. The output signals of the two oscillators are picked up by a magnetic coupling, which consists of a circle which is located in the vicinity of the oscillators and is not shown in the drawing for the sake of simplicity. The advantages of the invention emerge from the above description, in particular using the The circuits shown provide the ability to have a single tuner for receiving television channels broadcast over a wide range of bands without simultaneously making the tuning process critical. Furthermore, by performing the function of the oscillator 214 with three separate oscillators, it is possible to precisely delimit the television channel bands into which the tuner can be tuned in order to prevent the reception of unwanted channels, for example those in the areas that the television bands I. , II, III and separate the UHF bands. Another advantage of the tuning device described is that it enables a greater rejection of frame rate than has previously been possible, and also a reduction in intermodulation and distortion in the case of very strong signals or signals very close to another station great strength that is received.

Another advantage of the invention is the possibility of creating a tuner with the smallest adjustment requirements. The use of a single varicap diode and the automatic gain control device within the tuner means that parts with real values which differ significantly from the nominal values can be used without impairing the function.

Changes are of course possible within the scope of the invention. One of the changes that can be made is, for example, a different choice of the first intermediate frequency and the oscillator of fixed frequency. This has no influence on the function of the circuit if a first intermediate frequency is used which differs from 426 MHz. Any of the frequencies between the last TV channel on Band III and the first channel on the UHF band, or even higher than the last channel on the UHF band (roughly 1 GHz) can be used.

Another approach can be to use two oscillator use a variable frequency instead of three for the VHF and UHF bands. This solution does not make the tuning process more critical because the frequency change range of the single VHF oscillator is always smaller than that of the UHF oscillator, which is always the highest in all cases.

Claims (19)

1. Television receiver tuner for receiving all television channels on the VHF, CATV and UHF bands and for converting the received signal to a lower frequency, with an amplifier circuit for regulating the amplitude of the received signal and supplying it to a first mixer circuit, a Oscillator circuit of variable frequency for supplying the first mixing circuit with a reference oscillation and a second mixing circuit that receives the signal coming from the first mixing circuit and a reference oscillation that comes from a second oscillator of fixed frequency, characterized in that the received signals are in the VHF band, in CATV band and in the UHF band are converted by the first mixing circuit into a first intermediate frequency f [low] 1, which is on a frequency band lower and adjacent to the UHF television band, and that the second mixing circuit receives the signal from the first intermediate frequency f [low ] 1 converts to a second intermediate frequency f [low] 2, which is lower than the F frequency of the first TV channel belonging to the VHF band. 2. television receiver tuning device according to claim 1, characterized in that the required channel is tuned by a single variable capacitance device forming part of the variable frequency oscillator circuit. 3. Television receiver tuning device according to claim 1, characterized in that the variable frequency oscillator circuit consists of at least a first and a second variable frequency oscillator which are activated according to whether the required channel is on the VHF or on the UHF band lies. 4. A television receiver tuner according to claim 1, characterized in that the variable frequency oscillator circuit consists of three variable frequency oscillators which are activated according to whether the required channel belongs to a predetermined television channel band. 5. Television receiver tuning device according to claim 4, characterized in that the function of two of the oscillators can be carried out using a single oscillator on which the elements that determine the generated oscillation frequency are switched to the transition from one operating state to the other. 6. Television receiver tuning device according to one of claims 1 to 5, characterized in that the oscillators of variable frequency are voltage controlled. 7. Television receiver tuning device according to one of claims 1 to 6, characterized in that circuit means are provided for preventing the reception of signals belonging to unwanted frequency bands. 8. Television receiver tuning device according to claim 7, characterized in that the circuit means have activation means by means of which the oscillator circuit of variable frequency can generate oscillations which only belong to the required television channel bands. 9. television receiver tuning device according to one of claims 1 to 8, characterized in that the amplifier circuit has a first damping circuit which attenuates the signal in accordance with a first control signal that is generated by evaluating the information emanating from the video detector in the receiver, which of the device is downstream. 10. Television receiver tuning device according to one of claims 1 to 9, characterized in that the amplifier circuit has a second damping circuit which operates in accordance with the first control signal and a second control signal emanating from the second mixing circuit. 11. television receiver tuning device according to claim 9, characterized in that the first damping circuit has at least one PIN diode. 12. Television receiver tuning device according to claim 10, characterized in that the second damping circuit has at least one PIN diode. 13. Television receiver tuning device according to one of claims 1 to 12, characterized in that the second mixing circuit has means for determining the amplitude of the signal which is present at its output, and for supplying the second control signal. 14. Television receiver tuning device according to one of the Claims 1 to 13, characterized in that the amplifier circuit has at least one bandpass amplifier stage. 15. Television receiver tuning device according to claim 14, characterized in that the amplifier circuit has at least two bandpass amplifier stages and that the stages can each be activated individually in accordance with the television channel required. 16. Television receiver tuning device according to one of claims 1 to 15, characterized in that the frequency of the oscillator of variable frequency is equal to the sum of the received signal frequency and the first intermediate frequency f [low] 1. 17. Television receiver tuning device according to one of claims 1 to 16, characterized in that the frequency of the fixed frequency oscillator is equal to the difference between the first intermediate frequency f [low] 1 and the second intermediate frequency f [low] 2. 18. Television receiver tuning device according to one of claims 1 to 17, characterized in that the frequency f [low] 1 is roughly 426 MHz. 19. Television receiver tuning device according to one of claims 1 to 18, characterized in that the frequency f [low] 2 is large 36 MHz.