DE19818748C2 - TV tuner - Google Patents

Description

The invention relates to a television tuner according to the preamble of claim 1, in particular for use in navigation systems installed in vehicles.

Modern navigation systems in motor vehicles have a built-in television door ner, so that you can also receive television on the screen of a navigation system can watch programs.

Fig. 4 of the drawing shows in the form of a block diagram an already designed television tuner for a navigation system. As is apparent from Fig. 4, includes a remote sehtuner 31 is a VHS radio frequency unit 32 for selecting and outputting a ge desired television signal in the VHF band from the VHF television signals, a VHF-band mixer 33 for mixing the VHF television signal, which comes from the VHF radio frequency unit 32 with a local signal output from a VHF local oscillator 34 to obtain an intermediate frequency signal.

Similarly, the television tuner 31 includes a UHF radio frequency unit 35 for selecting and outputting a desired UHF television signal from the television signals of the UHF band, a UHF mixer 36 which converts the UHF television signal output by the UHF radio frequency unit 35 with one of one UHF local oscillator 37 ge mixed beat signal to obtain an intermediate frequency signal. In addition, the television tuner 31 includes an intermediate frequency unit 40 which has an intermediate frequency (IF) filter 38 for filtering out the IF signals from the VHF mixer 33 and the UHF mixer 36 and an IF amplifier 39 for amplifying that from the IF Filter 38 has filtered IF signal.

The VHF unit 32 includes a VHF input tuning circuit 31 which functions as an input tuning circuit which is tuned to a desired VHF television signal from the VHF television signals received via an antenna (not shown), a VHF radio frequency amplifier 42 for HF Amplification of the VHF television signals to which the VHF input tuning circuit 41 is tuned, and a VHF intermediate tuning circuit 43 , which serves as an interstage tuning circuit, to provide the television signal with a steep selectivity characteristic as amplified by the VHF radio frequency amplifier 42 to enter into the VHF mixer 33 .

Similarly, the UHF radio frequency unit 35 contains a UHF input tuning circuit 44 , which functions as an input tuning circuit which is tuned to a frequency of a desired UHF television signal of the UHF television signals received via the antenna, not shown, a UHF radio frequency amplifier 45 for HF Amplification of the UHF television signal supplied by the UHF input tuning circuit, and a UHF intermediate stage tuning circuit 46 for inputting the UHF television signal with steep selectivity characteristic, as amplified by the UHF high-frequency amplifier 45 , into the UHF mixer 36 . Although the VHF input tuning circuit 41 and the UHF input tuning circuit 44 are basically formed by a single tuning circuit is often observed that as well contain the VHF input tuning circuit 41 and the UHF-A gangsabstimmschaltung 44 is a band-stop filter or a Zwischenfre frequency rejector circuit to eliminate extraneous interference signals that are in the frequency band of the IF signal.

A television signal of a desired VHF band is selected by the VHF radio frequency unit 32 from the television signals of the VHF bands which are in the range from approximately 90 MHz to 220 MHz and reach the input terminal 47 . Thus, only the television signal of the selected VHF band is given via the VHF intermediate tuning circuit 43 to the VHF mixer 33 and mixed by this with a beat signal supplied by the VHF local oscillator in order to use this mixture to convert an intermediate frequency signal (IF Signal).

Similarly, a television signal of a desired UHF band is selected by the UHF radio frequency unit 35 from the television signals of the UHF band, which is between approximately 470 MHz and 770 MHz and reaches the input terminal 47 . Only the television signal of the selected UHF band is given via the UHF intermediate tuning circuit 46 to the UHF mixer 36 and mixed by this with a beat signal supplied by the UHF local oscillator 37 to obtain an IF signal. The IF signals thus supplied by the VHF mixer 33 and the UHF mixer 36 receive a predetermined selectivity characteristic by the IF filter 38 , are amplified by the IF amplifier 39 , and are then connected via the output connection 48 a subsequent demodulator (not shown).

If the above-described, already designed television tuner 31 is installed in a motor vehicle navigation system, the navigation system is disturbed by harmonics of a local signal output from a local oscillator of the television tuner 31 , in particular signals that the UHF local oscillator 37 delivers, so that this Navigation system cannot work properly.

In particular, the navigation system instructs the driving course to be observed in response to the waves (especially in response to GPS signals, that is to say signals from the so-called global positioning system) which are emitted by satellites at a frequency of 1.575 GHz. The receiver of the navigation system contains a filter with a bandwidth of approximately 3 MHz. However, if the television tuner 31 is in the receiving mode so that it can receive a television signal, for example of channel 56 (the Japanese television standard) of the television signal in the UHF band, the UHF reception oscillator 37 oscillates at a frequency of 788 MHz.

Although the local oscillator signal is input from the local UHF oscillator 37 to the UHF mixer 36 , fundamental waves as well as harmonic waves of the local reception signal are easily passed through the UHF mixer 36 and the UHF high frequency unit 35 in the direction of the input terminal 47 in the opposite direction the usual reception operation, in order to then be radiated outward from the input terminal 47 . Because the second harmonic (with a frequency of 1.576 GHz) in particular has a low order, its level is high. In addition, since the frequency of this second harmonic or first harmonic is very close to 1.575 GHz, i.e. the frequency of the GPS signal, and the bandwidth of the receiver of the navigation system is 3 MHz, the second harmonic of the beat signal easily reaches the receiver of the navigation system. From this it follows that a disturbance of the navigation system is inevitable.

In accordance with the preamble of claim 1, US 4,247,953 shows one TV tuner in which the damping device is a filter, the purpose of which in a be correct operating mode is to pass only signals of the VHF band, To block signals from the UHF band.

Similar television tuners are known from DE 36 06 660 A1, US Pat. No. 5,010,400 and US Pat. PS 4 340 975 known. Filters between input connector and input tuning circuits are generally used to hold frequencies that are used, for example, by the police, the Firefighters and other facilities can be used.

From US-PS 4 408 348 a multi-band television tuner is known, in which one Low-pass filter connected downstream of the input terminal serves only for such signals in the Tune in to a low frequency range of a band being received correspond, while a parallel branch of the input connection with a second Filter is equipped, which passes the other frequencies of the band to be received.

The object of the invention is to provide a television tuner in which a disturbance Navigation system through harmonics one from a local local oscillator generated beat signal can be prevented.

This object is achieved by the features of claim 1.

Advantageous embodiments of the television tuner are specified in the subclaims.

Exemplary embodiments of the invention are described in more detail below with reference to the drawings explained. Show it:

Fig. 1 is a block diagram of a television tuner according to an embodiment of the inven tion;

Fig. 2 is a circuit diagram for explaining an example of a damping device as used in the television tuner according to the invention;

Fig. 3 is a circuit diagram for explaining another example of a damping device, as used in the television tuner according to the invention; and

Fig. 4 is a block diagram of an already designed television tuner.

Fig. 1 shows a block diagram of a television tuner according to the invention in the form. A television tuner 1 contains an attenuation device 2 , for example a low-pass filter for attenuating a signal having a frequency which is higher than a maximum frequency (770 MHz of a television signal in the UHF band according to the Japanese television standard) of an antenna (not shown) TV signal, a VHF radio frequency unit 3 , which serves as a radio frequency unit to select and output a television signal from the VHF band of the television signals, a VHF mixer 4 as a mixer for frequency conversion of the television signal belonging to the VHF band, which is used by the VHF band High-frequency unit 3 is output, in an intermediate frequency signal (IF signal), and a VHF local oscillator 5 , which serves as a local oscillator for providing a local local signal for the VHF mixer 4 .

Furthermore, the television tuner 1 similarly contains a UHF radio frequency unit 6 , which serves as a radio frequency unit for selecting and outputting a received television signal in the UHF band of the television signals, a UHF mixer 7 as a mixer for frequency conversion of the television signal of the UHF band, which is output by the UHF high-frequency unit 6 , into an IF signal, and a UHF local oscillator 8 , which serves as a local local oscillator for providing a local signal for the UHF mixer 7 .

The television tuner 1 also includes an intermediate frequency circuit unit 11 , the IF filter 9 for filtering the IF signals from the VHF mixer 4 and the UHF mixer 7 , and an IF amplifier 10 for amplifying the IF Filter 9 received IF signal.

The VHF high-frequency unit 3 includes a VHF input tuning circuit 12 as an input tuning circuit, which is tuned to a frequency of a received VHF television signal from a VHF television signal received via an antenna (not shown), a VHF high-frequency amplifier 13 for High-frequency amplification of a VHF television signal to which the VHF input tuning circuit 12 has been tuned and a VHF intermediate tuning circuit 14 into which the VHF television signal having a steep selectivity characteristic and amplified by the VHF high-frequency amplifier 13 is inserted into the VHF- Mixer 4 is entered.

Similarly, the UHF radio frequency unit 6 contains a UHF input tuning circuit 15 , tuned to a frequency of a received UHF television signal of the UHF television signals received via an antenna (not shown), a UHF radio frequency amplifier 16 for radio frequency amplification of the UHF television signal, to which the UHF input tuning circuit 15 is tuned and a UHF intermediate tuning circuit 17 for inputting a UHF television signal with a steep selectivity characteristic, which was amplified by the UHF high-frequency amplifier 16 , into the UHF mixer 7 .

The damping device 2 consists of either a low-pass filter or a blocking circuit which is capable of damping the first harmonic of a local superimposition signal, in particular the UHF reception oscillator 8 . FIG. 2 shows an example of the damping device 2 , here formed by an M-branch low-pass filter with a corner frequency in the vicinity of approximately 900 MHz. A damping pole frequency (blocking frequency) of a blocking circuit formed by an inductance element 21 and a capacitance element 22 in parallel is set to such a frequency that the blocking circuit is able to damp harmonics of a local beat signal which are present in the vicinity of a signal which is received by the receiver of the navigation system. This makes it possible to effectively protect the navigation system from reception interference.

Since the receiver of the navigation system receives a GPS signal with a frequency of 1.575 GHz, the cut-off frequency is set to 1.576 GHz, which is the frequency of the first harmonic of the reception beat signal in channel 56 (channel 56 of the Japanese television standard) UHF local oscillator 8 is. If the blocking frequency is set to 1.576 GHz, the first harmonic of the reception beat signal can be effectively attenuated by this branch M low-pass filter, and thus the input of the signal into the receiver of the navigation system can be avoided. So if the navigation system receives the GPS signal with the frequency of 1.575 GHz, the navigation system can easily be protected from the reception interference. In fact, the blocking frequency does not always have to be set exactly at 1.576 GHz. If the cutoff frequency is set to a frequency close to 1.576 GHz, the harmonic of the reception beat signal can also be attenuated.

Although not shown, the damping device 2 may have a low-pass filter in which a capacitance element 22 of the damping device 2 according to FIG. 2 is omitted, the low-pass filter consisting only of the inductor 21 and a shunt capacitance element 23 , which is between one end of the Inductance element 21 and ground is connected. If the damping device 2 consists of the above-mentioned low-pass filter, it is possible to avoid interference in a wide range, which is caused by the harmonics of the overlay signal.

Fig. 3 shows another example of the damping device 2 , which here consists only of a blocking circuit, which is formed by an inductance element 24 and a capacitance element 25 in parallel.

If the resonance frequency (blocking frequency), which is determined by the value of the inductance element 24 and the value of the capacitance element 25 , is set to 1.576 GHz, that is to say the frequency of the harmonic of the reception oscillator signal in channel 56 of the UHF superposition oscillator 8 , can In this case, too, reliably protect the navigation system from the reception interference that would otherwise be caused by the harmonics of the beat signal of the television receiver.

While the VHF input tuning circuit 12 and the UHF input tuning circuit 15 are generally each formed by a single tuning circuit, it can often be observed that a bandstop or an IF blocking circuit is added to them in order to eliminate an external interference signal , which is present in the frequency band of the IF signal.

A television signal of a desired VHF band is then selected by the VHF radio frequency unit 3 from the television signals at the input terminal 18 of the VHF band lying between 90 MHz and 220 MHz. Only the television signal of the VHF band thus selected is input via the VHF intermediate tuning circuit 14 into the VHF mixer 4 and mixed by this with the beat signal formed by the VHF local oscillator 5 in order to achieve the frequency conversion into an IF signal.

Similarly, a television signal of a desired UHF band is selected by the UHF radio frequency unit 6 from the television signals input via the input terminal 18 of the UHF band lying between 470 MHz and 770 MHz. Only the television signal of the UHF band selected in this way is given via the UHF intermediate tuning circuit 17 to the UHF mixer 7 and mixed by this with the local signal supplied by the UHF local oscillator 8 to obtain an IF signal. The IF signals thus formed by the VHF mixer 4 and the UHF mixer 7 receive a predetermined selectivity characteristic from the IF filter 9 , are amplified by the IF amplifier 10 and then at the output connection 9 to a subsequent demodulator (not shown) or given a similar circuit.

As stated above, the television tuner according to the invention consists of an input port, input tuning circuits and reception oscilla lators and the damping device between the input and the input tuning circuits to dampen the signal, whose frequency is higher than the maximum frequency of the receiving one TV signal, the harmonics of the beat signal of the Reception oscillator of the television tuner can be prevented from  Input port to be emitted to the outside. This allows the receiver of a navigation system using this television tuner includes, before a disturbance by harmonics of the beat signal protect. Since according to the invention also the damping device between the input connector and the input tuning circuits arranged, needs the TV tuners designed in the area sensitive circuit can not be changed, but can be in simple Modify way by adding damping device. The Television tuners can therefore be produced with little effort.

Since the damping device in the television tuner according to the invention consists of the low-pass filter for filtering signals whose Frequencies above the maximum frequency of the television received signals lie, it is possible to be disturbed by harmonics of the over storage signals that are within the wide range to ver avoid.

Since the television tuner according to the invention also Damping device can consist of the blocking circuit that the upper waves of the beat signal received by the local oscillator and that near the frequency of the reception signal of the navigation system receiver can dampen existing harmonics, can effectively protect the navigation system from the interference that otherwise caused by the harmonics of the beat signal would.

Since in the television tuner according to the invention also the Sperrfre frequency of the blocking circuit is set to the frequency in the vicinity of 1.576 GHz, which is the frequency of the first harmonic of the local oscillator signal in channel 56 of the local oscillator, the first harmonic can be damped reliably.

Claims (3)

1. TV tuner comprising:
an input port ( 18 );
Input tuning circles ( 12 ; 15 );
Local oscillators ( 5 ; 8 ) that generate local beat signals; and
a damping device ( 2 ) which is located between the input connection ( 18 ) and the input tuning circuits ( 12 ; 15 ),
characterized in that
the damping device ( 2 ) consists of a blocking circuit that dampens harmonics of the beat signal at a frequency that is close to a signal frequency that is received by a receiver of a navigation system. 2. Tuner according to claim 1, wherein the blocking circuit ( 2 ) has a low-pass filter. 3. The tuner of claim 1, wherein the rejection frequency of the rejection circuit is close to 1.576 GHz, which is the frequency of the first harmonic of a beat signal of channel 56 (in Japan) of the local oscillator.