DE19734026A1 - Television tuner blocking circuit - Google Patents

Abstract

The circuit includes two blocking circuits (8,13) connected to the output of a mixer (2) which mixes the received signal and a superimposition frequency signal from the receiver oscillator. An intermediate signal is generated by the mixer. One blocking circuit receives a noise signal in the upper sideband directly above the intermediate frequency. The other receives a noise signal in the lower sideband directly below the intermediate frequency. At least one blocking circuit is variable. The blocking frequency of the variable circuit is differently set when receiving a VHF signal from that when receiving a UHF signal.

Description

The invention relates to a television tuner blocking circuit, in particular a blocking circuit depending on whether the VHF broadcast signal or the UHF broadcast signal is received, different blocking frequencies to block an interference signal of a lower adjacent channel and an interference signal of an upper adjacent channel of an intermediate frequency quenzsignals when the frequency bandwidths per channel for the VHF transmit signal are different than for the UHF transmit signal.

The VHF transmit signals and the UHF transmit signals differ in With regard to the transmission frequencies and frequency bandwidths per channel from country to country. According to the specifications, the frequency is bandwidth per channel 6 MHz for both VHF and UHF transmission signals in Japan and the United States while the bandwidth 7 MHz for VHF transmit signals and 8 MHz for UHF transmit signals in European countries.

Tuners for receiving VHF signals and UHF signals are typical usually with a blocking or suction circuit to intercept Interference signals from neighboring channels. The blocking circuit is in the output stage of a mixer that has an intermediate generated frequency signal, and it eliminates an interference signal of an upper adjacent channel and an interference signal of a lower adjacent Channel in the intermediate frequency signal.

Fig. 4 is a schematic diagram of an example of an already designed blocking circuit.

According to FIG. 4 is located between a mixer 41 and an intermediate frequency amplifier 42, a blocking circuit 40. The blocking circuit 40 includes a first blocking circuit 45 , consisting of a parallel circuit comprising a first capacitor 43 and a first inductor 44 , a second blocking circuit 48 , formed by a parallel circuit comprising a second capacitor 46 and a second inductor 47 , a parallel circuit 51 a third inductor 49 with a tap and a third capacitor 50 , a first DC blocking capacitor 52 , a second DC blocking capacitor 53 , a bypass capacitor 54 and a DC supply connection 55 . All of these components with the reference numerals 51 to 45 are connected in the manner shown in FIG. 1.

The first blocking circuit 45 is designed so that its resonance frequency corresponds to the frequency of the interference signal in an adjacent channel of the intermediate frequency signal, so that the interference signal is blocked on one side. The second blocking circuit 48 is designed so that its resonance frequency corresponds to the interference signal frequency of the other adjacent channel, so that this interference signal is intercepted on the other side. The parallel circuit 51 is tuned to the intermediate frequency and it extracts the intermediate frequency signal from the frequency mixture which comes from the mixer 41 .

The conventional television tuner blocking circuit efficiently catches the interference signal of the adjacent channel on the one hand and the interference signal of the Adjacent channel on the other hand from the intermediate frequency signal from when the circuit z. B. in Japan or in the United States is used where the frequency bandwidth per channel for both VHF and is also 6 MHz for UHF transmit signals.

However, if this conventional television tuner blocking circuit z. B. is used in European countries where the frequency bandwidth per Channel for the VHF signal 6 MHz in contrast to a frequency band width for the UHF signal is 7 MHz, this blocks conventionally le television tuner blocking circuit the interference signals of the adjacent channels probably on the one hand and on the other hand with VHF-Sendesigna  len, when receiving UHF signals, however, only the blocking signal one of the adjacent channels is filtered out of the intermediate frequency signal tert, while the interference signal of the other adjacent channel is not well off can be caught.

The invention is intended to solve the problem addressed above, and consequently it is an object of the invention to provide a television tuner blocking circuit ben, the interference signals with both VHF and UHF transmit signals can block from adjacent channels even if the frequency band width per channel is different for the VHF transmission signal than for the UHF transmission signal.

This problem is solved by the inventor specified in claim 1 dung. Advantageous further developments result from the Unteran sayings.

In the television tuner blocking circuit according to the invention there are two blocks circles are provided to intercept the interference signals from adjacent channels. At least one of the two blocking circles is a variable blocking circle trained, the blocking frequency can be changed. The lock frequency of the variable blocking circuit is received when receiving a VHF TV signal set differently than when receiving a UHF television signal nals.

If with this configuration the frequency bands per channel at VHF signal are different from the UHF signal, so the blocking can frequency of the variable blocking circuit set differently accordingly depending on whether the VHF or UHF television signal Will be received. In this way, interference channels from the bottom and upper adjacent channel in the received intermediate frequency signal intercepted effectively with both VHF and UHF signals will.  

If according to the preferred specified in the subclaims Refinements of the blocking circuit according to the invention the frequency bandwidth per channel for VHF reception is different than for UHF Reception, the at least one can be configured as a variable blocking circuit formed blocking circuit to be set to a blocking frequency VHF reception is different from UHF reception, so that it is disturbing channels from the adjacent channel on both sides of a receive channel in the Intermediate frequency signal can be blocked correctly, both when receiving VHF signals as well as when receiving UHF signals.

In the following, exemplary embodiments of the invention are described with reference to the Drawing explained in more detail. Show it:

Figure 1 is a schematic diagram of a first embodiment of a tuner disable circuit according to the invention.

FIG. 2 shows an example of the frequency response of an intermediate frequency output signal of the blocking circuit according to FIG. 1;

Fig. 3 is a schematic representation of a second embodiment of the tuner lock circuit according to the invention; and

Fig. 4 is a schematic diagram of an already designed blocking circuit for a tuner.

Fig. 1 shows a first embodiment of a tuner blocking circuit according to the invention for a tuner which corresponds to the European television standard.

FIG. 1 is designed as a balanced circuit tuner blocking circuit 1 of this embodiment between the Ausgangsan connections of a mixer 2 and the input terminals connected in an intermediate frequency amplifier 3. The blocking circuit contains a first blocking circuit 8 with a first capacitor 4 , a first inductor 5 , a first variable capacitance diode 6 and a second variable capacitance diode 7 , a second blocking circuit 13 with a second capacitor 9 , a second inductor 10 , a third variable Capacitance diode 11 and a fourth variable capacitance diode 12 , a tuning circuit 16 with a third inductor 14 with tap and a third capacitor 15 , a first DC blocking capacitor 17 , a second DC blocking capacitor 18 , a bypass capacitor 19 , four resistors 20 , 21 , 22 and 23 , a bias supply port 24 , a VHF select signal port 25, and a UHF select signal port 26 .

The first blocking circuit 8 contains the first capacitor 4 , the first inductance 5 and a series circuit comprising the first and the second variable capacitance diodes 6 and 7 , connected in parallel with the capacitance and the inductance, whereby a variable blocking circuit is formed. The first blocking circuit 8 is connected at one end to one of the output connections O 1 of the mixer 2 , with the other end to one of the input connections I 1 of the intermediate frequency amplifier 3 , specifically via the first DC blocking capacitor 17 . The node of the first variable capacitance diode 6 and the second variable capacitance diode 7 is connected via a resistor 20 to the VHF select signal port 25 , which is connected to ground via a resistor 21 . The second blocking circuit 13 contains the second capacitor 9 , the second inductor 10 and a series circuit connected in parallel therewith from the third variable capacitance diode 11 and the fourth variable capacitance diode 12 , and also forms a variable blocking circuit. The second blocking circuit 13 is connected at one end to the output terminal O₂ of the mixer 2 and at the other end via the second DC blocking capacitor 18 to the input terminal 12 of the repeater 3 . The connection node between the third and fourth variable capacitance diodes 11 and 12 is coupled via a resistor 22 to the UHF selection signal terminal 26 , which is connected to ground via a resistor 23 .

The tuning circuit 16 contains the third inductor 14 and the third capacitor 15 in parallel and is coupled at one end to one output O 1 of the mixer 2 and at the other end to the other output O 2 of the mixer 2 . The tap of the third inductor 14 is connected directly to the bias connection 24 and is also connected to ground via the bypass capacitor 19 .

The bias connection 24 is constantly supplied with a constant DC voltage (e.g. 5 V). The VHF select signal terminal 25 receives a constant DC voltage (e.g. 5 V) when receiving a VHF signal, while being grounded (0 V) when receiving a UHF signal. On the other hand, the UHF selection signal terminal 26 is kept at ground potential (0 V) when VHF signals are received and is fed with a constant DC voltage (e.g. 5 V) when UHF signals are received.

According to the European television standard, eleven channels, namely channel 2 to channel 12, are assigned to the VHF range, each channel having a frequency bandwidth of 7 MHz and a difference of 5.5 MHz between the video carrier frequency and the sound carrier frequency. In the UHF range there are 49 channels from channel 21 to channel 69 , with each channel having a bandwidth of 8 MHz with a distance between image carrier and sound carrier of 5.5 MHz. In the tuner, the intermediate frame frequency fp is set to 38.9 MHz and the sound intermediate carrier frequency fs to 33.4 MHz.

Fig. 2 shows an example of the frequency response of an intermediate frequency output signal of the blocking circuit of Fig. 1. A solid line corresponds to the frequency response when receiving VHF signals, a dashed line represents the frequency response when receiving UHF signals.

The frequency response illustrated in Fig. 2 will be discussed below. Assume that VHF channel 11 is received (frequency band from 216 MHz to 223 MHz, video carrier frequency 217.25 MHz and sound carrier frequency 222.75 MHz) and UHF channel 22 is received (frequency band from 478 to 486 MHz, Image carrier at 479.25 MHz and sound carrier at 486.75 MHz).

While receiving the VHF channel 11 , the mixer 2 selects a local oscillation frequency of 256.15 MHz, which is mixed with the reception frequency by an image intermediate frequency (P) of 38.9 MHz from the difference between the frequency of the beat signal of 256.15 MHz and the image carrier frequency of 217.25 MHz, and the intermediate sound frequency (S) of 33.4 MHz is derived from the frequency difference between the beat signal with the frequency of 256.15 MHz and a sound carrier frequency of 222.75 MHz .

An image interference signal P _v of 31.9 MHz is regarded as interference signals which impair the reception of the VHF channel 11 , namely the frequency difference between the frequency of the beat signal 256.15 MHz and the image carrier with the frequency of 224.25 MHz of the channel 12 lying immediately above the channel 11 , and a sound interference signal S _v of 40.4 MHz which corresponds to the frequency difference between the local beat signal with the frequency 256.15 MHz and the sound carrier frequency 215.75 MHz which is received immediately below NEN channel 11 corresponds to lying channel 10 . The first blocking circuit 8 and the second blocking circuit 13 must eliminate this image interference signal P _v and this sound interference signal S _v .

When receiving the UHF channel 22 , the mixer 2 selects a receiving oscillator signal with a frequency of 518, 15 MHz, which is mixed with the receiving frequency by an image intermediate frequency (P) of 38.9 MHz from the frequency difference between the beat signal to obtain the frequency of 518.15 MHz and the image carrier frequency of 479.25 MHz, it also derives a tone intermediate frequency (S) of 33.4 MHz from the frequency difference between the frequency of 518, 15 MHz of the local oscillator and a sound carrier frequency from 222.75 MHz.

The following are considered interference signals for the reception of UHF channel 22 : an image interference signal P _u of 30.9 MHz corresponding to the frequency difference between the local oscillator signal 518.15 MHz and the image carrier frequency of 487.25 MHz of that lying immediately above channel 22 Channel 23 , and a sound interference signal S _u of 41.4 MHz, corresponding to the frequency difference between the local oscillator signal at 518.15 MHz and the sound carrier frequency of 476.75 MHz of the channel 21 immediately below channel 22 . The first blocking circuit 8 and the second blocking circuit 13 must eliminate these image interference signals P _u and audio interference signals S _u .

Although the reception of VHF channel 11 and UHF channel 22 is discussed here by way of example, both circuits must of course also remove the interference signals when receiving other VHF and UHF channels.

There is one between the image interference signal P _u of 30.9 MHz in a channel immediately above a reception channel when receiving a UHF signal and the image interference signal P _v of 31.9 MHz in a channel immediately above a reception channel when receiving a VHF channel Frequency difference of 1 MHz. There is also a frequency difference of 1 MHz between the audio interference signal S _u of 41.4 MHz in a channel immediately below a reception channel upon receipt of the UHF transmission signal and the image interference signal S _v of 40.4 MHz in a channel immediately below a reception channel rend receipt of a VHF broadcast signal.

The first embodiment shown in FIG. 1 will be explained with reference to the frequency response in FIG. 2.

The mixer 2 mixes the frequencies of a received transmission signal and a local beat signal and gives to the blocking circuit 1 a frequency signal mixture containing an intermediate frequency signal (IF) ent, via the outputs O₁ and O₂. The blocking circuit 1 draws the IF signal from the frequency mix, which is supplied by the tuning circuit 16 , and supplies the resulting IF signal to the first and second blocking circuits 8 and 13, respectively.

When a tuner receives the VHF broadcast signal, a DC voltage of 5 V is applied to the bias terminal 24 , and a DC voltage signal of 5 V is applied to the VHF selection signal terminal 25 , while ground potential of 0 V is applied to the UHF selection signal terminal 26 . In the first blocking circuit 8 are on both connections to both the first and the second variable capacitance diodes 6 and 7 5 V, so that a voltage of about 0 V is applied to each diode. The total capacitance of the first variable capacitance diode 6 and the second variable capacitance diode 7 is increased, and the blocking frequency of the first blocking circuit 8 shifts to the lower side, so that it speaks approximately to the sound interference signal S _v of 40.4 MHz. In the second blocking circuit 13 , only the cathode of the third and fourth variable capacitance diodes 11 and 12 receives the voltage of 5 V, so that a voltage of approximately 5 V is applied to both diodes. The total capacitance from the third and fourth variable capacitance diodes 11 and 12 is reduced, so that the blocking frequency of the second blocking circuit 13 is shifted towards the higher side and corresponds approximately to the image interference signal P _v of 31.9 MHz.

When the tuner 1 receives the UHF signal, the bias terminal 24 is supplied with a voltage of 5 V, the VHF selection signal terminal 25 receives ground potential of 0 V and the UHF selection signal terminal 26 receives a voltage of 5 V. In the first Blocking circuit 8 receives only the cathode of the first and second variable capacitance diodes 6 and 7, a voltage of 5 V, so that there are about 5 V each at the diodes. The total capacitance from the first and second variable capacitance diodes 6 and 7 decreases, so that the blocking frequency of the first blocking circuit 8 shifts to the higher side and corresponds approximately to the audio interference signal S _u of 41.4 MHz. In the second blocking circuit 13 , both connections to the variable capacitance diodes 11 and 12 retain a voltage of 5 V, so that approximately 0 V are applied to each diode. The total capacitance from the third and fourth variable capacitance diodes 11 and 12 increases, and consequently the blocking frequency of the second blocking circuit 13 is shifted towards the lower side, so that it corresponds approximately to the interference signal P _u of 39.9 MHz.

The IF signal, from which the adjacent-channel interference signals P _v , P _u and the adjacent-channel interference signals S _v , S _{u are} already removed by the first blocking circuit 8 and the second blocking circuit 13 , the input terminal I 1 and the other input terminal I 2 of the Intermediate frequency amplifier 3 via the first DC blocking capacitor 17 and the second DC blocking capacitor 18 are supplied.

In this way, according to the first embodiment, when VHF signals are received as well as when UHF signals are received, the blocking frequencies of the first blocking circuit 8 and the second blocking circuit 13 are shifted into regions of higher or lower frequencies, depending on the difference in the bandwidth per Channel between VHF and UHF operation. As a result, the adjacent channel image interference signals P _v , P _u and the adjacent channel audio interference signals S _v , S _{u are} intercepted. Thus, the blocking circuit 1 supplies the IF signal with a frequency response according to the solid line in Fig. 2 when receiving a VHF channel and delivers the IF signal with a frequency response corresponding to the dashed line in Fig. 2 when a UHF Channel is received.

Fig. 3 is a schematic representation of a second embodiment of a tuner blocking circuit according to the invention, wherein, as in the first embodiment, the tuner speaks ent of the European television standard.

In FIG. 3, those components which correspond to the components from FIG. 1 are provided with the same reference numerals as there.

The second embodiment differs from the first embodiment in that the first embodiment includes the first blocking circuit 8 (variable blocking circuit) with the first capacitor 4 , the first inductor 5 , the first variable capacitance diode 6 and the second variable capacitance diode 7 , while the second embodiment contains a first blocking circuit 8 'with only a first capacitor 4 and a first inductor 5 , whereby a non-variable or fixed blocking circuit is formed. Furthermore, in the first embodiment, the latch circuit includes the resistors 20 and 21 and the VHF select signal terminal 25 , whereas the second embodiment does not include such components. Since there are otherwise no differences between the first and the second embodiment, no further discussion should be made. In the second embodiment, the first blocking circuit 8 'has a blocking frequency as a fixed blocking circuit, which is approximately matched to the sound interference signal S _v of 40.4 MHz when receiving VHF channels. The trap frequency for the first blocking circuit 8 'is fixed to the sound interference signal S _v of 40.4 MHz for the reception of both VHF and UHF channels. The second embodiment differs from the first embodiment in that when VHF channels are received, the audio interference signal S _v of 40.4 MHz is essentially intercepted, while when receiving UHF channels, the audio interference signal S _u of 41.1 MHz is partially intercepted is intercepted. The rest of the operation of the second embodiment is the same as that of the first embodiment.

The reason that the first blocking circuit 8 'is designed as a fixed blocking circuit in the second embodiment is that the effect of the sound interference signal S _u when receiving UHF channels turns out to be relatively mild compared to the effects of the image disturbance signal P _v Receiving VHF channels, the picture interference signal P _u when receiving UHF channels and the sound interference signal S _v when receiving VHF channels.

In the second embodiment, when receiving VHF channels and when receiving UHF channels, the first blocking circuit 8 'with its fixed blocking frequency blocks the adjacent-channel interference signals S _v , S _u , while the blocking frequency of the second blocking circuit 13 changes depending on the difference Bandwidth per channel shifts to the higher or lower frequency zone depending on whether a VHF or a UHF channel is being received, so that the adjacent channel image interference signals P _v , P _{u are} intercepted. The first blocking circuit 1 outputs the IF signal with a frequency response similar to the frequency response shown in FIG. 2.

Although the above embodiments were based on the European one TV standard explained, but the invention is not based on a sol Chen special tuner type limited. Other transmission systems are coming also considered for the invention.

As described above, if the bandwidth per channel is at VHF channels is different than UHF channels, at least one of two Blocking circuits designed as a variable blocking circuit, so that the blocking frequencies of the two blocking circuits depending on it be made different whether VHF or UHF channels received will. The adjacent channel interference signals on both sides of the reception channels within the intermediate frequency signal are in the required intercepted when receiving both VHF and Reception of UHF channels.

Claims (3)

1. TV tuner blocking circuit with two blocking circuits ( 8 , 13 ; 8 ', 13 ) which are connected to the output of a mixer ( 2 ) which mixes a received television signal and a local signal formed by a local oscillator and generates an intermediate frequency signal, whereby one blocking circuit intercepts an interference signal in the upper adjacent channel immediately above the intermediate frequency signal and the other blocking circuit interferes with an interference signal in the lower adjacent channel immediately below the intermediate frequency signal, at least one of the two blocking circuits ( 8 , 13 ; 8 ', 13 ) being designed as a variable blocking circuit is whose blocking frequency is variable, the blocking frequency of the variable blocking circuit when receiving a VHF television signal is set differently than when receiving a UHF television signal, thereby blocking the two interference signals. 2. The circuit of claim 1, wherein the mixer ( 2 ) is a mixer with balanced outputs, wherein one of the two blocking circuits to one line from a pair of output lines of the mixer and the other blocking circuit to the other line of the pair of output lines the mixer is connected. 3. A circuit according to claim 1 or 2, wherein the variable blocking circuit contains a variable capacitance diode, the blocking frequency being changed by changing a voltage applied to the variable capacitance diode ( 6 , 7 ; 11 , 12 ).