KR950009770Y1 - High freq signal distribution apparatus - Google Patents

Abstract

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Description

High Frequency Signal Distribution Device

1 is a circuit diagram of a conventional high frequency signal distribution device

2 is a circuit diagram of a high frequency signal distribution apparatus according to an embodiment of the present invention

* Explanation of symbols for main parts of the drawings

20: amplifier 22: distributor

C1 ~ C3: Capacitor D1: Diode

L1 to L3: Inductor Q1: Transistor

R1 to R8: Resistance T1: Transformer

The present invention relates to a high frequency signal distribution apparatus that can improve the signal-to-noise ratio by distributing at least two high frequency signals received by the aerial without gain attenuation.

A typical high frequency signal distribution device distributes at least two radio frequency (hereinafter referred to as "RF") signals received by an aerial to a tuner having at least two or more tuners for distributing at least two or more RF signals. Supply to the device. However, the conventional high frequency signal distribution device reduces the gain of the RF signal in the process of distributing the RF signal, thereby lowering the signal-to-noise ratio (S / N) and receiving the RF signal when a weak electric field is received through the aerial. There was a problem that the sensitivity dropped significantly. The problem of the conventional high frequency signal distribution apparatus will be described in detail with reference to FIG.

FIG. 1 illustrates the first transformer Tl for inputting an RF signal from an incoming air line (not shown) via the input line 11, and the intermediate tap and ground potential GND of the transformer Tl. A conventional high frequency signal distribution device having a capacitor C1 connected therebetween is shown. The first transformer Tl matches the impedance with the aerial line and the middle tap of the second transformer T2 via its middle tap without loss of the RF signal from the aerial line flowing through the input line 11. To the end. The capacitor Cl compensates for the high frequency component of the RF signal supplied from the middle tap of the first transformer Tl to the middle tap of the second transformer T2. The second transformer T2 uniformly distributes the RF signal flowing from the middle tap of the first transformer Tl to its middle tap into two signals, and distributes the divided RF signals to both the taps and the first. It is sent out to a tuning device (not shown) via the second output lines 12 and l3. In addition, the resistor R1 connected between both taps of the second transformer T2 serves to match impedance.

As described above, the conventional high frequency signal distribution device has a problem of severely attenuating the gain of the RF signal applied to the tuner by its impedance because it is configured to prevent and distribute the loss of the RF signal using a transformer. . Due to the above problems, the conventional high frequency signal distribution apparatus suffers from a severe reduction in the reception sensitivity of a television receiver when an RF signal of a weak electric field is received.

Accordingly, an object of the present invention is to provide a high frequency signal distribution apparatus that can improve the signal-to-noise ratio by distributing at least two high frequency signals received by an aerial without attenuation of gain.

In order to achieve the above object, the high-frequency signal distribution device according to the present invention, the bypass inductor for bypassing the overcurrent signal flowing through the signal input line from the aerial of the antenna to the ground potential, and the energy charged in the inductor A high frequency signal input means comprising a back EMF absorbing diode for absorbing the back EMF generated by the first coupling capacitor, and a first coupling capacitor for removing the DC noise signal included in the high frequency signal from the air flowing through the signal input line; A transistor having a base connected to a single coupling capacitor, two resistors and one inductor connected in series between the collector and the base of the transistor, another resistor and a capacitor connected in series between the emitter and the ground potential of the transistor; A series connection between the power supply line and the collector of the transistor A second amplifying capacitor which removes the noise signal of the DC component included in the high frequency signal amplified from the collector of the transistor, the other resistor and inductor, and a high amplification factor of the high frequency signal from the air flowing through the coupling capacitor Amplification means for amplifying with; And a transformer having an intermediate tap connected to the second coupling capacitor and both taps connected to the first and second signal output lines, between the both taps of the transformer and between the first signal output line and the ground potential. And a resistor connected between the second signal output line and the ground potential, respectively, to distribute the high frequency signal amplified from the amplifying means into two high frequency signals having the same magnitude, and to distribute the distributed high frequency signal to the first signal. And distribution means for transmitting through the second signal output line.

Hereinafter, with reference to the accompanying Figure 2 an embodiment of the present invention will be described in detail.

Referring to FIG. 2, an amplifier 20 for receiving an RF signal received by an aerial line (not shown) via the signal input line 21 and the coupling capacitor C1, and the signal input line 21. And a high frequency signal distribution device according to an embodiment of the present invention having a diode D1 and an inductor L1 connected in series between a base line GND. The inductor L1 bypasses an overcurrent call due to a lightning strike flowing through the signal input line 21 toward the ground potential GND so that the overcurrent is not applied to the diode D1 and the amplifier 20. do. The diode D1 absorbs and processes back EMF generated by the energy charged in the inductor L1 to prevent the electrostatic breakdown of the amplifier 20 connected to the coupling capacitor C1. As a result, the inductor L1 and the diode D1 function to protect the amplifier 20 from the high voltage caused by lightning or the like on the signal input line 21 through the aerial. In addition, the coupling capacitor C1 removes the DC catch signal included in the RF signal from the air line flowing through the signal input line 21. In addition, the amplifier 20 included in the high frequency signal distribution device according to the embodiment of the present invention is driven by the DC supply voltage Vcc applied through the power supply line 23 to the coupling capacitor C1. Amplify the RF signal from the incoming air at a constant amplification rate. To this end, the amplifier 20 has two resistors R2 and R3 connected in series between the transistor Q1 connecting its base to the coupling capacitor C1 and the collector and base of the transistor Q1. And an inductor L2, a resistor R5 and a capacitor C2 connected in series between the emitter of the transistor Q1 and the ground potential GND. The transistor Q1 includes the coupling capacitor C1. Amplify the RF signal to the input line 21 is supplied to its base via a) and outputs the amplified RF signal to the coupling capacitor (C3) via its collector. The amplification factor of the transistor Q1 is the resistance R1 and the inductor L2 and the emitter and the ground potential of the transistor Q1 which are directly connected between the power supply line 23 and the collector of the transistor Q1. It is determined by the impedances of the resistor R ₅ and the capacitor C ₂ connected in parallel between (GND). The bias voltage of the transistor Q _l is determined by the resistance voltage division ratio of the resistor R ₄ connected between the resistor R ₃ and the base and the base potential GND of the transistor Q _l . . The resistor (R ₅₎ and the capacitor (C ₂₎ is maintained stably the amplification factor of said transistor (Q _l) to form a current negative feedback path of the transistor (Q _l). The negative feedback current amount of the transistor Q ₁ is determined by the resistance value of the resistor R ₅ . The capacitor C ₂ bypasses an unnecessary high frequency noise signal. In addition, the resistor R ₂ and the inductor L ₃ provide a voltage negative feedback path to the transistor Q ₁ , of which the resistor R ₂ determines the amount of voltage fed back according to its resistance value. In addition, the inductor L ₃ increases the gain of the transistor Q ₁ in the frequency band (near 700 MHz in the case of television) determined by its impedance according to the magnetic resonance characteristic. The coupling capacitor C ₃ , which receives the amplified RF signal from the collector of the transistor Q ₁ , removes a noise signal of a DC component included in the amplified RF signal.

In addition, the high frequency signal distribution device according to the embodiment of the present invention distributes the amplified RF signal from the collector of the transistor Q _l in the amplifier 20 introduced through the coupling capacitor (C ₃ ) and this distribution And a distributor 22 for transmitting the received RF signal through the first and second signal output lines 25 and 27. The distributor 22 is a transformer T1 having its intermediate tap connected to the coupling capacitor C ₃ and its both taps connected to the first and second signal output lines 25 and 27, and the transformer. A resistor R ₆ connected between both taps of T _l is provided. The transformer T ₁ equally converts the amplified RF signal from the collector of the transistor Q _] in the amplifier 20 introduced into its intermediate tap via the coupling capacitor C ₃ into two signals. The two divided RF signals are supplied to the first and second signal output terminals 25 and 27 via their respective tabs. The resistor R ₆ has different input impedances of a first tuner (not shown) and a second tuner (not shown) to be connected to the first signal output line 25 and the second signal output line 27. Even though the distributed RF signals have the same magnitude, the impedances of the first and second tuners and the transformer T _l are matched. The transformer T ₁ is a balanced-to-unbalanced transformer suitable for matching the first and second tuners with the amplifier 20. The divider 22 includes a resistor R ₇ connected between the first signal output line 25 and the ground potential GND, the second signal output line 27, and the ground potential GND. It further comprises a resistor R ₈ connected to the surgeon. The two resistors R ₇ and R ₈ have the function of the load resistance of the transformer T ₁ .

As described above, the high frequency signal distribution device of the present invention provides an advantage of amplifying a high frequency signal received by an aerial to compensate for the gain attenuation of the RF signal attenuated by the distributor. Due to the above advantages, the high frequency signal distribution device of the present invention compensates the gain attenuation of the RF signal by the splitter so that the television receiver can stably detect the television signal even when a weak electric field RF signal is received and improve the signal-to-noise ratio. It offers the benefits of doing so.

Claims (2)

(Correction) a bypass inductor for bypassing an overcurrent signal flowing from the aerial of the antenna through the signal input line to the base potential, a reverse electromotive force absorption diode for absorbing back electromotive force generated by energy charged in the inductor, and A high frequency signal input means comprising a first coupling capacitor for removing a DC noise signal included in a high frequency signal from an air line flowing through a signal input line; A transistor having a base connected to the first coupling capacitor, two resistors and one inductor connected directly between the collector and the base of the transistor, another resistor connected in parallel between the emitter and the ground potential of the transistor, and A capacitor, another resistor and inductor connected directly between the power supply line and the collector of the transistor, and a second coupling capacitor for removing the noise signal of the DC component included in the amplified high frequency signal from the collector of the transistor. Amplifying means for amplifying a high frequency signal from an aerial flowing through the coupling capacitor at a constant amplification rate; and A transformer having an intermediate tap connected to the second coupling capacitor and both tabs connected to the first and second signal output lines, between the both taps of the transformer and between the first signal output line and the ground potential and Comprising resistors connected between the second signal output line and the ground potential, respectively, the high frequency signal amplified from the amplifying means is divided into two high frequency signals having the same size, and the divided high frequency signals are divided into the first and second signals. Frequency signal distribution device consisting of distribution means for transmitting over a signal output line (delete)