KR950012950B1 - Stabilization circuit of input signal for ic tunor - Google Patents

Abstract

an IC double conversion tuner including a first mixer for up-converting a radio frequency input signal into an oscillating signal of a first oscillator and a second mixer for down-converting an output signal of the first mixer into an oscillating signal of a second oscillator; a band-pass filter including variable tuning VHF low and high band-pass filters and a variable tuning UHF band-pass filter which respectively select a VHF low band, a VHF high band and a UHF band according to a selection voltage and filter only a radio frequency band of a corresponding line station channel in the selected band; and a wide-band low noise amplifier for amplifying the gain of the radio frequency signal outputted from the band-pass filter up to a predetermined level in accordance with an AGC control signal.

Description

IC signal tuner input signal stabilization circuit

1 is a circuit diagram of a conventional IC tuner.

2 is a schematic circuit diagram of the present invention.

3 is a detailed circuit diagram showing one embodiment of the present invention.

4 is a detailed circuit diagram showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

90: band pass filter 100: low noise amplifier

110: UHF band pass filter 120: UHF amplifier

130: VHF low pass filter 140: VHF high pass filter

150: VHF amplifier 160: UHF variable modulation band pass filter

170: VHF variable modulation band pass filter 180: UHF / VHF wideband amplifier

The present invention relates to an input signal stabilization circuit of an IC tuner used to receive a broadcast signal, and more particularly, to an input tuner stabilization circuit of an IC tuner for minimizing interference of unwanted signals generated around the received signal by converting the tuner into an IC. It is about.

With the recent development of IC technology, it is necessary to convert a tuner for receiving broadcast signals such as TV signals, AM / FM signals, DBS signals, etc. into one or several ICs, that is, single chip high frequency integrated circuits (MMICs). It was possible.

A general internal circuit configuration of such an IC tuner is shown in FIG.

1 is a double conversion (Doub1e conversion) tuner circuit, in which the RF input signal from the antenna input terminal 1 is amplified by the RF amplifier 10, and the amplified signal is oscillated by the first oscillator 20. FIG. The frequency is mixed in the first mixer 30 and converted into a first intermediate frequency signal.

Typically, up to this point is an up converter stage.

The intermediate frequency (IF) output signal in which the RF amplification signal and the oscillation frequency signal are mixed and output from the first mixer 30 is passed through the first IF amplifier 50 through the first band pass filter 40 and then the second mixer ( 70).

The second mixer 70 mixes the amplified signal of the first IF amplifier 50 and the oscillation frequency of the second oscillator 60 to produce a second IF signal and provides the second IF amplifier 80 to the second IF amplifier 80. 80 amplifies the IF signal output from the second mixer 70 and sends it to the IF output stage 2.

Typically, the configuration from the first band pass filter 40 to the second IF amplifier 80 becomes a down coverter stage.

However, the IC of the tuner can reduce the cost of the product and reduce the size of the product, so that the economical effect is good. However, when there is a strong unnecessary signal around the received signal, it is difficult to exclude this unnecessary signal. Due to saturation concerns, it is difficult to receive both strong and weak signals of a broadband.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to interfere with a signal of another channel adjacent to a channel currently being received, or to signal interference by intermodulation or signal interference by intermodulation. And an input signal stabilization circuit of an IC tuner capable of minimizing the deterioration of characteristics generated from an antenna and enhancing a dynamic range characteristic of an input strong or weak signal.

The technical configuration for realizing the above object of the present invention is a band pass filter configured for each received signal band at the front end of the IC tuner or a variable tuning circuit, and receives a signal from an automatic gain regulator and receives a strong or weak signal at a wide band. It characterized in that it consists of a low noise amplifier for controlling the automatic gain with respect to.

The internal technical configuration of the band pass filter and the low noise amplifier includes a UHF band pass filter for removing unnecessary signals of a broadcast signal from the 50 MHz to 900 MHz band, and amplifying the output signal of the UHF band pass filter to a predetermined level. A UHF amplifier output to the tuner, a VHF low band pass filter that receives a VHF low band signal to remove unwanted signals, a VHF high band pass filter that receives a VHF high band signal to remove unwanted signals, and the VHF It is characterized by consisting of a VHF amplifier to amplify the output signal of the low / high band pass filter to a predetermined level and output to the IC tuner.

Another internal technical configuration of the band pass filter and the low noise amplifier includes a UHF variable modulation band pass filter for receiving an UHF signal and removing an unnecessary signal, and a VHF variable modulation type band pass for receiving an VHF signal and removing an unnecessary signal. And a UHF / VHF wideband amplifier which amplifies the output signal of the UHF / VHF variable modulation band pass filter to a predetermined level and outputs the IC signal to an IC tuner.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic block diagram of the present invention, in which a band pass filter 90 and a low noise amplifier 100 are sequentially connected to the front end of the IC tuner 200, and the low noise amplifier 100 has an automatic gain control stage 3. Connect to operate according to control signal of).

The band pass filter 90 divides a low band, a high band, and a UHF band into several reception bands, for example, a VHF of a TV signal, so that the band switching is performed by a switching circuit or a filtering frequency according to the reception band. Consists of a variable-tuned band pass filter in which is moved.

The low noise amplifier 100 is composed of a wideband low noise amplifier (LNA) that can cover all received signal bands, or, like the band pass filter 90, a low noise amplification circuit for each received band to automatically adjust the gain. It is configured to show stable signal output characteristics for strong and weak signals depending on the signal.

In the circuit configured as described above, the desired RF received signal output from the band pass filter 90 is input to the wideband low noise amplifier 100.

In the low noise amplifier 100, the RF input signal gain of the reception band is stabilized by the AGC signal of the automatic gain control stage 3 and provided to the input terminal of the IC tuner 200. Therefore, the IC tuner 200 always provides a constant level of RF. An input signal is to be provided.

This will be described in more detail below.

3 is a detailed configuration diagram of the band pass filter 90 and the low noise amplifier 100 according to the present invention and configured to perform band switching for each reception band of a TV signal.

In FIG. 3, a band pass filter 110 for receiving a UHF broadcast signal is connected to the RF input terminal 1, and an internal configuration thereof includes a condenser and a coil component, which are filter elements. Connect D ₁ ) (D ₂ ) and connect UHF power terminal (6) at the same time.

The UHF band pass filter 110 connects a UHF amplifier 120 configured by connecting a resistor, a condenser, and a coil to an amplifying transistor 121, and the UHF power stage 6 and an automatic gain control stage are connected to the amplifier 120. (3) to connect.

Meanwhile, the VHF low band filter 130 and the high band filter 140 are connected to the RF input terminal 1, and an internal configuration thereof includes a capacitor and a coil component, which are filter elements, and includes a switching diode for signal path ( D ₃ ) (D ₄ ), and at the same time, a low band receiving power stage 5 is connected to the low band filter 130, and a high band receiving power stage 4 is connected to the high band filter 140. Configure by connecting each.

The VHF amplifier 150 is connected to the common contact 7 of the UHF low band filter 130 and the high band filter 140 and the common contact 8 of the UHF amplifier 120 and the automatic gain control stage 3. The internal structure is configured by connecting a resistor, a capacitor, and a coil to the amplifier transistor 151.

Then, the switching diodes D ₅ and D ₆ are connected to the UHF amplifier 120 and the VHF amplifier 150, respectively, and are connected to the RF output terminal 2.

In FIG. 3 configured in this way, of the broadcast signals of the 50 MHz to 900 MHz band input from the antenna (not shown), a voltage appears at the UHF power supply stage 6 when receiving the UHF band (300 to 900 MHz). This voltage conducts the switching diode D ₁ of the UHF band pass filter 100 and the switching diode D ₅ of the RF output terminal 2.

When the two switching diodes D ₁ and D ₅ are conducted, unwanted unwanted signals are removed from the broadcast signals input through the UHF band pass filter 110, and the desired signals from which the unnecessary signals are removed are UHF amplifiers 120. After amplified by a signal of a predetermined level in the amplifying transistor 121 of the ()) is output to the IC tuner 200 via the RF output terminal 2 through the switching diode (D ₅ ).

In a similar operation, when the VHF low band (50 to 130 MHz) is received while receiving a broadcast signal, a voltage appears at the power supply terminal 5 for low band reception. This voltage conducts the switching diode (D ₃ ) and the switching diode (D ₂ ) of the VHF low band pass filter (130) and at the same time passes through the common contact (7) to the switching diode (D ₆ ) of the RF output terminal (2). Turn on.

Therefore, the VHF low band signal input through the conducting switching diode D ₂ is removed through the VHF low band pass filter 130, and unwanted unwanted signals are removed, and the desired VHF low band is removed. after the signal is amplified through the conductive switching diode (D ₃₎ to the gain signal level desired at the amplifier transistor 151 of the VHF amplifier (150), RF output (2) via said the conductive switching diode (D ₃₎ It is output to the IC tuner 200 via.

In addition, when the VHF high band (130 to 300MHz) reception is received, a voltage is generated at the power supply stage 4 for high band reception, and the switching diode D ₄ and the switching diode of the VHF high band pass filter 140 are received. At the same time as (D ₂ ), the switching diode (D ₆ ) of the RF output terminal (2) is conducted via the common contact (7).

Accordingly, the VHF high band signal input through the conductive switching diode D ₂ is passed through the VHF high band pass filter 140, and after the unwanted signal is removed, the switching diode (VHF high band signal) is conducted. After amplified by the VHF amplifier 150 through D ₄ ), it is output to the IC tuner 200 via the switching diode D ₆ and the RF output terminal 2.

4 illustrates another embodiment of the present invention, in which an unnecessary signal is removed by using a variable tuning filter.

In FIG. 4, the UHF for receiving the UHF broadcast signal is coupled to the RF input terminal 1 with the variable shaping band pass filter 160. Its internal configuration consists of a capacitor, a coil, and a resistor, and a switching diode (D ₇ ) (D ₈ ) for forming a UHF RF signal path on the input and output sides, and on the switching diode (D ₇ , D ₈ ). The UHF power supply terminal 6 which shows the voltage for controlling these switching on is connected and comprised.

In addition, a VHF variable modulation band pass filter 170 for receiving a VHF broadcast signal is connected to the RF input terminal 1. Its internal structure consists of a capacitor, a coil, and a resistor as a filter element, and a switching diode (D ₉ ) for forming a VHF RF signal path is provided on the output side, and this switch, a diode (D ₉ ), and a switching diode for VHF low band tuning (D ₁₂ ) is connected to switch on the voltage of the VHF low-band receiving power stage (4), the switching diode (D ₉ ) and VHF high-band switching switching diode (D ₁₀ , D ₁₁ ) is VHF high band It is connected to be switched on with the voltage of the receiving power supply terminal (5). Meanwhile, the variable capacitance diode VD ₁ of the UHF variable modulation band pass filter 160 and the variable capacitance diode VD ₂ -VD _{5 of} the VHF variable modulation band pass filter 170 are connected to a tuning power supply stage 9. Connect so that tuning voltage of (tuning voltage) is applied.

The UHF / VHF wideband amplifier 180 is connected to the common contact 11 of the UHF and VHF variable modulation bandpass filters 160 and 170 by connecting a resistor, a capacitor, and a coil to the amplifying transistor 181. An output terminal 2 is connected, and an automatic gain control stage 3 is connected to a base of the transistor 181 so that an AGC signal is provided through a resistor, and a B + is connected to the RF output terminal 2 through a resistor, a coil, and a capacitor. The power stages 17 are connected to each other.

The tuning voltage tuning voltage supplied to each of the variable capacitor diodes is the same voltage as the oscillation frequency control voltage supplied to the first oscillator 20 of the IC tuner 200.

In FIG. 4 configured as described above, when UHF reception is performed, a voltage is applied to the UHF power supply stage 6 so that the switching diode D ₇ (D ₈ ) of the UHF variable modulation band pass filter 160 is conducted.

Therefore, after the unwanted unwanted signal of the UHF received signal is removed by the filter elements, only a desired signal is amplified by the UHF wideband amplifier 180 to a certain level through the common contact 11, and this amplified signal is outputted to the RF output stage ( 2) is provided to the IC tuner 200 as a stable UHF RF input.

On the other hand, when VHF high band reception is applied to the high-band receiving power supply terminal 4, the switching diode (D ₉ -D ₁₁ ) of the VHF variable modulation band pass filter 170 is conducted, VHF low band reception When the voltage is applied to the low band receiving power supply stage 5, the switching diodes D ₉ and D _{12 of} the VHF variable modulation band pass filter 170 are turned on, so that each VHF high or VHF low band tuning is performed. After the unwanted signal is removed through the filter circuit, only the RF signal of the desired VHF high or VHF low band is amplified by the VHF wideband amplifier 180 to a predetermined level, and the amplified signal is passed through the RF output stage 2 to the IC. It is provided to the tuner 200 as a stable VHF RF input.

At this time, a band including the VHF high or VHF low band selection voltage or the channel selected by the power supply stage 6 generated in each of the power stages 4 and 5 is selected, and then the band of the tuning power stage 9 in the selected band is selected. Since the RF band of the corresponding channel is filtered and output by the tuning voltage, the RF signal of which the gain (intensity) is stable and without interference between adjacent bands and adjacent channels can be provided to the IC tuner 200 as an input.

As described in detail above, the present invention can reinforce the deterioration phenomenon of the tuner, which is expected when the entire tuner is IC (MMIC), that is, the interference rejection ability and the dynamic range characteristic of strong and weak signal reception. That has an outstanding effect.

Claims (1)

A first mixer 30 for up-converting the RF input signal to the oscillation signal of the first oscillator 20, and a down-converting output signal of the first mixer 30 to the oscillation signal of the second oscillator 60; In an IC-converted double conversion tuner including two mixers 70, VHF low, VHF high and UHF bands are selected according to respective band selection voltages in front of the tuner, and the selected channels are tuned according to the tuning voltages of the channel. A band pass filter 90 including a variable-tuned VHF low and high band pass filter and a variable-tuned UHF band pass filter for filtering only the RF band of the corresponding channel in the band, and outputting from the band pass filter 90 And a wideband low-tone amplifier 100 for amplifying and outputting the gain of the RF signal to a predetermined level according to the AGC control signal.