JPH0238522Y2 - - Google Patents

Description

[Detailed explanation of the idea]

Industrial Application Field This invention relates to a high frequency receiving circuit for a television receiver equipped with a VHF tuner and a UHF tuner. Background Art and its Problems In a high frequency receiving circuit of a television receiver equipped with a VHF tuner and a UHF tuner,
The output load of the VHF tuner frequency mixing circuit,
As is already known, a device that is used in common with the output load of a video intermediate frequency amplification circuit for amplifying a video intermediate frequency signal outputted by a UHF tuner is constructed as shown in FIG. 1. The VHF signal (television signal) input from the VHF antenna ANT is passed through the first bandpass filter 1 and the high frequency amplifier circuit 2, which constitute the input tuning circuit.
The signal is then supplied to a second bandpass filter 3 having a channel selection means to select a desired channel, and the output _VRF is converted into a video intermediate frequency signal _VIF of a predetermined frequency in a frequency mixing circuit 4. .
5 is a local oscillator for frequency mixing. The video intermediate frequency signal V _IF is supplied to the next stage video intermediate frequency amplification circuit 6 and amplified. For the frequency mixing circuit 4, a double-balanced type as described later has recently been used due to the adoption of ICs. Therefore, this frequency mixing circuit 4 cannot be shared for UHF, and the UHF signal receiving system is provided separately from the input to the video intermediate frequency amplification circuit. That is, the UHF television signal is supplied to the second bandpass filter 13 via the first bandpass filter 11 and the high frequency amplification circuit 12, a desired UHF channel is selected, and the output _URF is subjected to frequency mixing. The signal is supplied to a frequency mixing circuit (diode mixer) 14 having a diode for converting it into a video intermediate frequency signal _UIF having the same frequency as that described above. 15 is a local oscillator for frequency mixing. The video intermediate frequency signal _UIF is supplied to the video intermediate frequency amplification circuit 6 for VHF via the video intermediate frequency amplification circuit 16. Note that this example shows a case where the circuits indicated by chain lines are integrated into an IC on the same substrate. When configuring the high frequency receiving circuit 10 in this way, the load connected to the final stage transistor (output transistor) configuring the frequency mixing circuit 4 for VHF is the video intermediate frequency amplifying circuit 16 for UHF.
The structure is such that it is commonly used as a load for the final stage transistor (output transistor) that constitutes the transistor. FIG. 2 shows an example of a specific circuit configuration. As the frequency mixing circuit 4 for VHF, a double-balanced type is used. That is, this is a first differential circuit 21 consisting of transistors Q ₁ and Q ₂ ,
Second operating circuit 2 consisting of transistors Q ₃ and Q ₄
The common emitters of the two common emitters are connected to a third differential circuit 23 consisting of transistors Q ₅ and Q ₆ . Then, the channel selected by the third differential circuit 23 is
A VHF signal V _RF is supplied through terminal 24 and the first
By commonly supplying the local oscillation signal to the second differential circuits 21 and 22 through the terminal 25,
A frequency-mixed video intermediate frequency signal V _IF is obtained on the load resistor R ₁ and R ₂ sides. The video intermediate frequency signal V _IF is supplied to the VHF video intermediate frequency amplification circuit 6 via DC cut capacitors C ₁ and C ₂ , respectively. This amplifier circuit 6 uses a differential amplifier composed of a pair of transistors Q ₈ and Q ₉ . Therefore, each transistor Q ₈ ,
A video intermediate frequency signal _VIF amplified to a predetermined value is obtained from the collector of _Q9 . The UHF video intermediate frequency amplification circuit 16 is composed of a transistor Q ₇ whose emitter is grounded, and its output terminal collector is directly connected to the collector of the transistor Q ₄ which constitutes the second differential circuit 22 in this example. Ru. Therefore, load resistor R ₂ also functions as a load resistor for transistor Q ₇ . _R3
is an emitter resistor for gain setting. Now, in this circuit configuration, the gain of the UHF video intermediate frequency signal U _IF is smaller than the gain of the VHF signal V _RF supplied to the frequency mixing circuit 4, so when considering the compatibility between the two, the video intermediate frequency amplification The circuit 16 must increase the gain of the video intermediate frequency signal _UIF . Video intermediate frequency amplification circuit 16
The gain G _U of is given by G _U =R ₂ /R ₃ +26/I _C , where I _C is the collector current flowing through the transistor _Q7 . Here, since the load resistor _R2 is for gain setting for the VHF signal _VRF , this value cannot be changed. Therefore, it is necessary to change the resistor R ₃ to obtain a predetermined gain _GU . For example, the gain when R ₃ = 20Ω is set.
If the compatibility of both gains is satisfied by increasing G _U by 6 dB, a new resistance value R′ ₃ is required to obtain a gain G′ _U that is increased by 6 dB.
Assuming that G′ _U =2G _U ∴R ₂ /R′ ₃ +26/I _C =R ₂ /R ₃ +26/I _C R ₃ =20Ω and I _C =3mA, R′ ₃ =5.7(Ω). There must be. However, when circuits 4, 6, and 16 are made into monolithic ICs as described above, if the value of resistor _R'3 is small, the temperature characteristics will deteriorate and the collector current I _C will fluctuate following temperature changes. Because it comes to that,
It becomes impossible to maintain the gain G′ _U at the set value. Purpose of the invention Therefore, in this invention, an arbitrary gain can be set in such a high frequency receiving circuit without being affected by temperature characteristics. Summary of the invention Therefore, the high frequency receiving circuit according to this invention is
A load resistor is connected to the output transistor provided in the VHF frequency mixing circuit, and the VHF video intermediate frequency signal obtained from this output transistor is supplied to the video intermediate frequency amplification circuit via the resistor. An output transistor provided in a video intermediate frequency amplification circuit for use is connected to a connection point between the resistor and an input stage of the video intermediate frequency amplification circuit so that the load resistor serves as a common load resistor. Ru. The gain of the UHF video intermediate frequency amplification circuit can be arbitrarily set using the resistor. Embodiment Next, an example of the high frequency receiving circuit 10 according to the invention will be described in detail with reference to FIG. 3 and subsequent figures. In this invention, as shown in FIG. 3, in a configuration in which the load resistor R ₂ of the frequency mixing circuit 4 is also used as the load resistor of the video intermediate frequency amplification circuit 16 for UHF, the amplification transistor
Between the connection point q of the collector of Q ₇ and the collector of the differential transistor Q ₄ , to which the load resistor R ₂ is connected,
A resistor _R0 is connected to set the gain of the UHF video intermediate frequency signal _UIF . Therefore, this resistor R ₀ together with the above-mentioned resistor R ₂ acts as a load resistor for the transistor Q ₇ . Therefore, when receiving UHF signals,
The gain (power gain) G _U of the video intermediate frequency amplification circuit 16 is G _U =R ₂ +R ₀ /R ₃ +26/I _C , and a predetermined gain can be obtained without reducing the value of the resistor R ₃ . For example, as mentioned above, to obtain twice the gain with R ₃ = 20Ω,
A resistor R ₀ that satisfies R ₀ = R ₂ may be used. Furthermore, when receiving a VHF signal, the input impedance of the video intermediate frequency amplification circuit 6 is very large, so the newly inserted resistor R ₀ can be practically ignored, and the resistor R ₀ There is almost no loss in the video intermediate frequency signal _VIF due to this. Of course, since the load resistor R ₂ is constant, the conversion gain of the frequency mixing circuit 4 does not change. In addition, with this invention, the gain G _U can be increased without reducing the value of the resistor R ₃ , so the temperature characteristics are excellent, and the video intermediate frequency signal U _IF changes depending on the temperature.
The gain does not change significantly. How much the gain G _U changes depending on the temperature is
It can be determined by measuring whether the collector current I _C flowing through the transistor Q ₇ changes with temperature. The temperature characteristics can be measured using the circuit shown in FIG. In the figure, transistor _Q'7 is a transistor
Therefore, _the emitter resistor R′ ₃ corresponds to R ₃ and R′ ₀ corresponds to (R ₀ + R ₂ ), respectively.
Collector current I' _C corresponds to I _C. Reference numeral 30 denotes a base bias circuit, which performs temperature compensation using diode-connected transistors Q _a to Q _c in order to prevent the base potential from changing due to temperature. The data obtained by this measurement circuit is shown below.
1>.

[Table] As is clear from <Table 1>, the smaller the resistance value R' ₃ is, the greater the variation in the collector current I' _C with respect to temperature changes, and accordingly the gain G _U becomes larger. It will fluctuate. According to this experiment, it is found that when the resistance value R' ₃ is set to 15Ω or less, the collector current I' _C fluctuates to such an extent that it cannot be put to practical use. Therefore, if the resistance value R ₃ is selected to be around 5Ω in order to double the gain G _U as in the past, it is impossible to implement it in an actual receiving circuit. It is proven that the circuit cannot arbitrarily set the gain of the UHF video intermediate frequency amplification circuit. Note that if the resistance value _R'3 is made small, the distortion characteristics will naturally deteriorate, and the problem of cross modulation will also occur. In the embodiments described above, the frequency mixing circuit 4 for VHF is not limited to a double balance mixer type. Connection point q may be connected to the collector of transistor Q ₁ and resistor R ₁ may be used as a common load. Effects of the invention As explained above, according to the configuration of this invention, without changing the conversion gain of the frequency mixing circuit 4 and without deteriorating the temperature characteristics,
It is possible to obtain the effect that the gain of the UHF video intermediate frequency amplification circuit 16 can be arbitrarily set with an extremely simple configuration. Therefore, as mentioned above, this invention is extremely suitable for application when the circuits 4, 6, and 16 are formed into monolithic ICs.

[Brief explanation of the drawing]

Fig. 1 is a system diagram showing an example of a high frequency receiving circuit to explain this invention, Fig. 2 is a concrete connection diagram of the main parts of the conventional device, and Fig. 3 is an example of a high frequency receiving circuit according to this invention. FIG. 4 is a connection diagram showing an example of a temperature characteristic measuring circuit. 4 is a frequency mixing circuit for VHF, 6 is a video intermediate frequency amplification circuit, 14 is a frequency mixing circuit for UHF,
16 is a video intermediate frequency amplification circuit for UHF, R ₂ is a common load resistor, and R ₀ is a gain setting resistor.

Claims (1)

[Scope of utility model registration request] A load resistor is connected to the output transistor provided in the VHF frequency mixing circuit, and the VHF video intermediate frequency signal obtained from this output transistor is supplied to the video intermediate frequency amplification circuit via the resistor. An output transistor provided in a video intermediate frequency amplification circuit for use is connected to a connection point between the resistor and the input stage of the video intermediate frequency amplification circuit so that the load resistor serves as a common load resistor, and A high frequency receiving circuit in which the gain of the UHF video intermediate frequency amplification circuit can be arbitrarily set depending on the device.