KR900002659Y1 - Television tuner - Google Patents

Abstract

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Description

TV tuner

1 is a block diagram of one embodiment of a television tuner of the present invention.

2 is a specific circuit diagram of the main part of FIG.

3 is a block diagram of a conventional television tuner.

* Explanation of symbols for main parts of the drawings

3: first antenna tuning circuit 4: first RF amplifier circuit

5: tuning circuit between first stage 6: mixing circuit

7: 1st local oscillation circuit 8: 2nd antenna tuning circuit

9: second RF amplifier circuit 10: second stage tuning circuit

12: second local oscillation circuit 21: IF output tuning circuit

SW: switching circuit

The present invention relates to a wideband television tuner for receiving VHF bands, CATV bands, and UHF bands.

For example, CATV to fill the gap between the VHF channels of the channels VLOCH (CH _{2 to} CH ₆ ) and VHICH (CH _{7 to} CH ₁₃ ) and the UHF channels of CH _{14 to} CH _{83 in} the United States, again these channel frequencies. The channel is set. Specifically, Table 1 is the same.

TABLE 1

Fig. 3 shows a block diagram showing the circuit configuration of a television tuner capable of receiving such a wide range of channels.

In FIG. 3, the signals of the VHF band and the CATV band are received by the first antenna 1, pass through the filter 2, and remove unnecessary signals to the first and second antenna tuning circuits 3 and 8. Supplied. Here, the signals of the VHF band and the CATV band are separated into the first frequency band of the frequency of 54 to 282 MHz and the second frequency band of the frequency of 282-47 MHz. In the first antenna tuning circuit 3, the desired signal is tuned from the signal of the first frequency band, and in the second antenna tuning circuit 8, the desired signal is tuned from the signal of the second frequency band. The output of the first antenna tuning circuit 3 is applied to the mixing circuit 6 via the switching circuit SW via the first RF amplifier circuit 4 and the first stage inter-tuning circuit 5 again. One oscillation signal of the local oscillation circuit 7 is mixed and the intermediate frequency signal is extracted by the IF output tuning circuit 21 and output to the IF output terminal 22. In addition, a first signal path is formed by the first antenna tuning circuit 3, the first RF amplifier circuit 4, and the first end tuning circuit 5. The output of the second antenna tuning circuit 8 is supplied to the second mixed circuit 11 via the second RF amplifier circuit 9 and the second stage tuning circuit 10, and the second local oscillation. Mixed with the oscillation signal of the circuit 12, the intermediate frequency signal is extracted by the second RF output tuning circuit 13 and supplied to the mixing circuit 6 via the switching circuit SW. At this time, the mixing circuit 6 operates as an amplifier, and the intermediate frequency signal is amplified and output from the IF output tuning circuit 21 to the IF output terminal 22.

In addition, a second signal as the second antenna tuning circuit 8, the second RF amplifier circuit 9, the second stage tuning circuit 10, the second mixing circuit 11, and the second RF output tuning circuit 13; The path is formed.

In addition, the UHF signal, which is the third frequency band, is received by the second antenna 14, and the desired signal is tuned by the third antenna tuning circuit 15, and the third RF amplifier circuit 16 and the third stage tuning circuit are tuned. Supplied to the third mixed circuit 18 via (17), mixed with the oscillation signal of the third local oscillation circuit 19, and the intermediate frequency signal is extracted and switched by the third IF output tuning circuit 20. It is supplied to the mixing circuit 6 via the circuit SW.

At this time, the mixing circuit 6 operates as an amplifier, and the intermediate frequency signal is amplified and output from the IF output tuning circuit 21 to the IF output terminal 22.

In the conventional television tuner, the second mixing path 11 and the second IF output tuning circuit 13 are included in the second signal path for receiving the second frequency band. There is a problem that it is not bonded. The second IF output tuning circuit 13 is included as a component of a coil having a large inductance value, and the shape is relatively large.

Therefore, since the parts are compactly and compactly disposed in a small space, unnecessary radiation is easily generated from the coil, and various disturbance wave suppression ratios are deteriorated. In addition, since the signal of the second frequency band passes through two tuning circuits of the second IF output tuning circuit 13 and the IF output tuning circuit 21, the bandwidth of the output waveform is higher than that of the signal of the first frequency band. There is a problem of narrowing. Therefore, if the bandwidth of the output waveform of the signal of the second frequency band is enlarged and the passband of the second IF output tuning circuit 13 is enlarged, the signal of the adjacent channel cannot be supported and intermodulation interference is generated.

The object of the present invention is to solve the problems of the conventional television tuner described above, and the television has approximately the same bandwidth as the output waveform of the first frequency band and the second frequency band, and has a simple circuit configuration and is suitable for miniaturization. To provide a tuner.

In order to achieve this object, the television tuner of the present invention superimposes the oscillation signal of the first local oscillation circuit on the output signal of the first signal path of the first frequency band and is applied to the output signal of the second signal path of the second frequency band. The oscillation signal of the second local oscillation circuit is superimposed, and either one of the first and second signal paths is selectively connected to the mixing circuit by a switching circuit, and the intermediate frequency signal is IF output tuned from the output of the mixing circuit. It is configured to extract from the circuit.

The oscillation signal of the first local oscillation circuit is superimposed on the output of the first signal path of the first frequency band, and the oscillation signal of the second local oscillation circuit is superimposed on the output of the second signal path of the second frequency band, Since the first and second signal paths are selectively connected to the mixing circuit in the switching circuit, the signals of the first and second frequency bands are both output through the same mixing circuit and the IF output tuning circuit. The bandwidth of the waveform is about the same.

In addition, since the second signal output tuning circuit is not required for the second signal path as in the related art, the circuit configuration is simple, and the miniaturization is easy, and furthermore, since the second IF output tuning circuit is not required, no unnecessary radiation is generated. The interference suppression ratio can be improved.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 1 and 2. 1 is a block diagram of one embodiment of a television tuner of the present invention, and FIG. 2 is a specific circuit diagram of the main part of FIG. In FIG. 1 and FIG. 2, the same block as the 3rd figure is attached | subjected with the same code | symbol, and the overlapping description is abbreviate | omitted.

In FIG. 1, the difference from that shown in FIG. 3 is that the first frequency band consists of a first antenna tuning circuit 3, a first RF amplifier circuit 4, and a first stage tuning circuit 5; The oscillation signal of the first local oscillation circuit 7 is superimposed on the output signal of the first signal path to the second RF amplification circuit 9 and the second stage tuning circuit 10 of the second antenna tuning circuit 8. The oscillation signal of the second local oscillation circuit 12 is superimposed on the output signal of the second signal path of the second frequency band, and the third IF output tuning circuit of the first and second signal paths and the third frequency band. It connects 20 to either of the mixing circuits 6 by the switching circuit SW. In addition, the second mixing circuit 11 and the second IF output tuning circuit 13 are deleted. More specifically, according to FIG. 2, the output terminal of the first stage tuning circuit 5 and the output terminal of the first local oscillation circuit 7 are connected together to the anode of the first switching diode 30. At the same time, the power supply terminal 32 is connected to the power supply terminal 32.

In addition, the output terminal of the second stage tuning circuit 10 and the output terminal of the second local oscillation circuit 12 are connected to the anode of the second switching diode 33 together with the power supply resistor 34. It is connected to the terminal 35.

The output terminal of the third IF output tuning circuit 20 is connected to the anode of the third switch diode 36 and to the power supply terminal 38 via the power supply resistor 37. The cathodes of the first, second, and third switching diodes 30, 33, and 36 are connected to the first gate G ₁ of the MOSFET 39 and grounded via a bias resistor 40 at the same time. The second gate G ₂ of the MOSFET 39 is connected to the drain D via the capacitor 43 and the resistor 42 in parallel, and at the same time through the resistor 43. The source S is connected to the drain D via the source resistor 44 and the capacitor 45 in parallel.

The drain D is connected to the IF output terminal 22 via the IF coil 47 and the direct current blocking capacitor 48 in series. The connection point of the IF coil 47 and the DC blocking capacitor 48 is grounded via the capacitor 49 and connected to the power supply terminal 51 via the power supply resistor 50. In this circuit configuration, the switching circuit SW is constituted by the first, second, and third switching diodes 30, 33, and 36, and the mixed circuit 6 is formed by the MOSFET 39, the IF coil 47, and the like. ) And IF output tuning circuit 21 are configured.

When a positive voltage is applied to the power supply terminal 32, a forward current flows through the first switching diode 30 so that the first signal path is connected to the mixing circuit 6, and the second and third switching diodes ( 33 is conducted, the second signal path is connected to the mixing circuit 6, and is interrupted from the first and third signal paths. When a positive voltage is applied to the power supply terminal 38, the third signal path is connected to the mixing circuit 6 to block the first and second signal paths. In addition, the feed resistors 31, 34, 37 are set to appropriate values for the bypass resistor 40, so that the signals of the first, second, and third frequency bands are mixed and amplified. The MOSFET 39 can be set in a state that is optimal for mixing and amplifying signals in the frequency band.

Therefore, the output signals of the first and second frequency bands are extracted by the same IF output tuning circuit 21, so that the bandwidths of the output waveforms of the intermediate frequency signals are almost the same.

Furthermore, as in the prior art, the interference suppression ratio can be improved without requiring the second IF output tuning circuit 13 without generating unnecessary radiation, and the circuit configuration is simple, making it easy to miniaturize.

As described above, the television tuner of the present invention superimposes the oscillation signal of the first local oscillation circuit on the output of the first signal path of the first frequency band and the second local part on the output of the second signal path of the second frequency band. Since the oscillation signals of the oscillation circuits are superimposed and their first and second signal paths are selectively connected to the mixing circuit by the switching circuit, the signals of the first and second frequency bands are the same as the mixing circuit and the IF output tuning. The bandwidth of the output waveform of the intermediate frequency signal output through the circuit is almost the same. Moreover, the conventional circuit configuration is not required for the second signal path and the circuit configuration is simple, and the miniaturization is easy, and furthermore, the second IF output tuning circuit is not required, and unnecessary copying is not generated. It shows the excellent effect that the interference suppression ratio can be improved.

Claims (1)

The oscillation signal of the first local oscillation circuit 7 is superimposed on the output signal of the first signal path of the first frequency band, and the output signal of the second signal path of the second local oscillation circuit 12 is superimposed on the output signal of the second signal path of the second frequency band. The oscillation signal is superimposed, and either one of the first and second signal paths is selectively connected to the mixing circuit 6 by a switching circuit, and the intermediate frequency signal is output from the output of the mixing circuit to the IF output tuning circuit 21. TV tuner, characterized in that extracted from).