KR0151994B1 - Super high frequency tuner for large width receiver - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a satellite broadcasting tuner for wideband reception applied to a satellite broadcasting receiver (SHF receiver), and more particularly to a satellite broadcasting tuner for wideband reception, which can be used widely without restriction of a low noise converter (LNB) or region. .

Technical means of the present invention by mixing the first and second high frequency amplification unit (110,130) for amplifying a high frequency signal induced from the antenna, and the output signal and the detection signal of the second high frequency amplification unit (130) to generate an intermediate frequency signal A mixer 150 for outputting, an intermediate intermediate frequency amplifier 160 amplifying the output signal of the mixer 150, and an intermediate frequency tuned to an intermediate frequency output signal of the primary intermediate frequency amplifier 160 In the tuner for satellite broadcasting comprising a frequency tuning unit 170 and a second intermediate frequency amplifier 180 for amplifying and outputting the output signal of the intermediate frequency tuning unit 170 to the demodulator, the primary high-frequency amplifier A high frequency tuning unit 120 for tuning a high frequency signal output from the 110 to a wide band; It is provided with a wide-area local oscillator 140 for oscillating the oscillation frequency in a wide band.

Description

Satellite Broadcast Tuner

1 is an internal block diagram of a conventional satellite broadcast tuner.

2 is an internal block diagram of a satellite broadcast tuner according to the present invention.

3 is a detailed circuit diagram of the wide-area high frequency tuning part 12 shown in FIG.

4 is a detailed circuit diagram of the wide-area local oscillator 140 shown in FIG.

* Explanation of symbols for main parts of the drawings

110: first high frequency amplification unit 120: wide area high frequency tuning unit

130: second high frequency amplification unit 140: wide area local oscillation unit

150: mixer 160: first intermediate frequency amplifier

170: intermediate frequency tuning unit 180: second intermediate frequency amplifying unit

190: PLL circuit part

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a satellite broadcasting tuner for wideband reception applied to a satellite broadcasting receiver (SHF receiver), and more particularly to a satellite broadcasting tuner for wideband reception, which can be used widely without restriction of a low noise converter (LNB) or region. .

In general, satellite broadcasting is a super high frequency signal of the SHF band (SHF: approximately 10 kHz) transmitted from the stationary satellite over the equator is focused on the parapolar antenna, the bandwidth of the ultra-high frequency band from 500 MHz to 800 MHz It contains programs of satellite broadcasting from 1 channel to 24 channels.

The focused ultra-high frequency is converted into a high frequency signal of a UHF band (UHF: Ultra High Frequency, about 1 kHz) in a low noise block downconverter (LNB) installed in a parapolar antenna, and the converted high frequency is a satellite broadcast tuner. Is converted to an intermediate frequency of 480MHz.

The satellite transmission band is gradually expanding, for example, the C band (3.7 ㎓ ~ 4.2 ㎓), the Ku band (11.7 ㎓ ~ 12.2 ㎓) and the European Communication Satellite (ECS) band (10.95 ㎓) in Europe. ~ 11.7㎓, Authert band (12.25㎓ ~ 12.75㎓), etc.

In consideration of the various satellite broadcasting bands as described above, low-noise converters (LNBs) are developing low-noise converters with oscillation frequencies of 9.75 kHz, 10.00 kHz and 10.75 kHz to fit the frequency range of the satellite broadcasting tuner.

1 is an internal circuit diagram of a conventional satellite broadcast tuner.

In Fig. 1, the conventional arrangement is that 1 is a primary high frequency amplification unit, which firstly amplifies a high frequency signal inputted from an antenna. 2 is a high frequency tuning unit, which selects and outputs only a high frequency signal by tuning to a high frequency signal from the primary high frequency amplifying unit. 3 is a secondary high frequency amplification unit, which amplifies and outputs the high frequency signal tuned by the high frequency tuning unit. 4 is a local oscillator, which generates an oscillation frequency and outputs it to the mixer. 5 is a mixer, which mixes the oscillation frequency from the local oscillation unit with the high frequency signal from the second high frequency amplification unit and outputs an intermediate frequency. 6 is the first intermediate frequency amplification unit, which amplifies and outputs the intermediate frequency output from the mixer. 7 is an intermediate frequency tuning section, which tunes to an intermediate frequency and outputs only the intermediate frequency. 8 is a secondary intermediate frequency amplifying unit, which amplifies and outputs the intermediate frequency tuned by the intermediate frequency tuning unit.

The signal output from the second intermediate frequency amplifier 8 is detected by the FM detection IC which is the next step, and a baseband signal is output.

The conventional tuner for satellite broadcasting configured as described above will gradually use a variety of low noise converters due to the wider satellite broadcasting, and there is a problem that the specification of the tuner must be changed according to the low noise converter handled accordingly.

Accordingly, an object of the present invention is to solve the above problems, and to provide a satellite broadcasting tuner for wideband reception, which can be widely used without restriction of a low noise converter (LNB) or region.

The present invention as a means for achieving the above object is to output the intermediate frequency signal by mixing the first and second high frequency amplification unit for amplifying the high frequency signal induced from the antenna, the output signal and the oscillation signal of the second high frequency amplification unit A mixer, a first intermediate frequency amplifying unit for amplifying an output signal of the mixer, an intermediate frequency tuning unit for tuning an output signal of the first intermediate frequency amplifier unit to an intermediate frequency, and an output signal of the intermediate frequency tuning unit A tuner for satellite broadcasting including a secondary intermediate frequency amplifier for outputting to a demodulator, comprising: a tuning switching unit for switching a high frequency signal output from the primary high frequency amplification unit, and a high frequency signal switched by the tuning switching unit A low pass tuning filter for tuning the signal to a low high frequency band, and a high frequency band for the high frequency signal switched by the tuning switching unit. Tuning and broadband high frequency tuning unit including a tuning filter for eokyong; A low frequency local oscillation circuit for oscillating the oscillation frequency corresponding to the high frequency signal output from the low frequency tuning filter of the wide area high frequency tuning unit, and an oscillation frequency corresponding to the high frequency signal output from the high frequency tuning filter of the wide area high frequency tuning unit A high frequency local oscillation circuit and a switching function corresponding to a switching operation of the tuning switching unit of the wide area high frequency tuning unit to provide the mixer with one of two oscillation frequencies oscillated from the low frequency local oscillation circuit and the high frequency local oscillation circuit. By providing a local local oscillation unit including an oscillation switching unit operating.

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

2 is an internal circuit diagram of a satellite broadcast tuner according to the present invention.

110 is a primary high frequency amplification unit, which first amplifies the high frequency signal induced by the antenna.

Reference numeral 120 denotes a wide frequency high frequency tuning unit, which is a tuning switching unit 122 for switching a high frequency signal outputted from a primary high frequency amplifying unit, and a high frequency signal switched by the tuning switching unit to 700MHz to 1700MHz. A low pass tuning filter 124, and a high pass tuning filter 126 for tuning a high frequency signal switched by the tuning switch to 1800 MHz to 2500 MHz.

130 is a secondary high frequency amplification unit, which amplifies and outputs a high frequency signal tuned by the high frequency tuning unit.

140 denotes a wide area local oscillation unit, which is output from a low frequency local oscillation circuit 144 for oscillating an oscillation frequency corresponding to a high frequency signal output from a low frequency tuning filter of a wide area high frequency tuning unit, and a high frequency tuning filter of the wide area high frequency tuning unit. A high frequency local oscillation circuit 146 for oscillating an oscillation frequency corresponding to a high frequency signal, and two oscillation frequencies oscillated from the low frequency local oscillation circuit and the high frequency local oscillation circuit, which are selectively provided to the mixer; An oscillation switching section 148 is configured to switch in correspondence with the switching operation of the tuning switching section of the high frequency tuning section.

150 is a mixer, which mixes the oscillation frequency from the local oscillator and the high frequency signal from the second high frequency amplification unit to output an intermediate frequency. 160 is a first intermediate frequency amplifying unit, which amplifies and outputs the intermediate frequency output from the mixer. 170 is an intermediate frequency tuning unit, which tunes to an intermediate frequency and selects and outputs only an intermediate frequency. 180 is a second intermediate frequency amplifying unit, which amplifies and outputs the intermediate frequency tuned by the intermediate frequency tuning unit. 190 is a phase locked loop (PLL), which synchronizes the oscillation frequency of the local local oscillation unit with a desired frequency.

The wide-area local oscillator 140 is a power supply switching operation corresponding to the switching operation of the oscillation switching unit 148 to provide power to the low-frequency local oscillator 144 and the high-frequency local oscillator 146 alternatively. Section 142.

FIG. 3 is a detailed circuit diagram of the high frequency tuning unit 120 shown in FIG.

The tuning switching unit 122 connects the diode D1 and the diode D2 in parallel, and one connection point between the anode terminal and the cathode terminal of the diode D1 and the diode D2 is connected through a capacitor C0. The output terminal of the primary high-frequency amplifier 110 is connected to the power supply B1 ⁺ through the resistor R1 and the capacitor C1. In addition, the other power supply terminal B2 ⁺ is connected to the anode terminal of the diode D1 through the resistors R3 and R4 and simultaneously connected to the cathode terminal of the diode D2 through the resistors R3 and R5. To configure.

The diodes D1 and D2 are preferably pinned diodes whose resistance is variable depending on the voltage.

The low pass tuning filter 124 comprises a tuning circuit composed of varactor diodes VD1 and VD2 and capacitors C4 and C5, and a coil L1 at an anode end of the diode D1 of the tuning switch 122. ) Is connected to the tuning voltage terminal Vt through the resistors R7 and R8 and the capacitors C6 and C8.

The high-pass tuning filter 126 is composed of a strip line coil (L2, L3), varactor diodes (VD3, VD4) and condensers (C10, C11), the diode of the tuning switch 122 It is configured by connecting to the cathode end of D2 via the coil L4 and the capacitor C9, and connecting to the tuning voltage terminal Vt through the resistors R10 and R8 and the capacitors C12 and C8.

4 is a detailed circuit diagram of the local oscillator 140 shown in FIG.

The oscillation switching unit 148 connects the diode D3 and the diode D4 in parallel, and connects one side of the anode and cathode terminals of the diode D3 and the diode D4 through the capacitor C22. It is connected to the one input terminal of the mixer 150, and is connected to the power supply B3 ⁺ through the resistor R21 and the capacitor C21. In addition, the other power supply terminal B4 ⁺ is connected to the anode terminal of the diode D3 through the resistors R24 and R22 and simultaneously connected to the cathode terminal of the diode D4 through the resistors R25 and R22. To configure.

The low-pass local oscillation circuit 144 includes a resonant circuit composed of a stripline coil L22, a capacitor C29, and varactor diodes VD21 and VD22, and a transistor Q1 and resistors R26 to R29. The resonant circuit is connected to the satellite synchronous loop (PLL) circuit section 190 through the resistor R32, and the collector stage of the transistor Q1 is oscillated through the capacitors C24 and C26.

It is configured by connecting to the any end of the diode D3 of the switching unit 148.

The high frequency local oscillation circuit 146 includes a resonant circuit composed of a stripline coil L24, a capacitor C34, and varactor diodes VD23 and VD24, and a transistor Q2 and resistors R33 to R36. An amplification circuit, and the resonant circuit is connected to the phase locked loop (PLL) circuit section 190 through a resistor R32, and the collector stage of the transistor Q2 is switched for oscillation through the capacitors C26 and C31. It is configured by connecting to the anode end of the diode D3 of the unit 148.

Here, in the figure reference numeral of B ^+, B1 ^+, B2 ^+, B3 ^+, B4 ⁺ is above the power stage B1 ^+, B3 ⁺ is a High signal and the Low signal is selectively applied to, B ^+, B2 ^+, B4 ⁺ is a power supply that provides a constant constant voltage at all times. C28 and C33 are coupling capacitors, and C27 and C32 are bypass capacitors.

Hereinafter, the operations and effects of the present invention will be described in detail with reference to FIGS. 2, 3, and 4.

In FIG. 2, the ultra-high frequency signal from the satellite (approximately 10.70 kHz to 12.75 GHz) is transmitted from a high frequency signal (approximately 700 MHz to 2500) in a low noise converter (aka LNB) installed in a satellite broadcasting antenna (aka parapolar antenna). MHz is converted into satellite broadcasting tuner.

The high frequency signal inputted to the satellite broadcasting tuner has different bands of the high frequency signal according to the type of the low noise converter (aka LNB). For example, when the band of the ultra high frequency signal is approximately 10.70 Hz to 12.75 Hz, When a low noise converter is installed, the band of the high frequency signal is 700 MHz to 2750 MHz, and a pair of 9.70 kHz (for the 10.70 ㎓ to 11.70 초 band) and 10.70 ㎓ (for the high frequency signal 11.70 ㎓ to 12.75 ㎓ band) are formed. When the low noise converter is installed, the bands of the high frequency signals are 1000 MHz to 2000 MHz and 1000 MHz to 2050 MHz, respectively.

The high frequency band is 700 MHz to 2750 MHz, 1000 MHz to 2000 MHz, and 1000 MHz to 2050 MHz. The high frequency tuning unit 120 according to the present invention provides the 700 MHz to 1700 MHz band and the 1800 MHz to 2500 MHz. By tuning to, it is possible to cover broadband.

Specifically, the high frequency signal input from the antenna is first amplified by the first high frequency amplification unit 110 and then input to the wide area high frequency tuning unit 120.

The wide area high frequency tuning unit 120 tunes the input high frequency signal to the band 700 MHz to 1700 MHz by the low frequency tuning filter 124 by the switching operation of the tuning switching unit 122 or the high frequency tuning filter ( 126) and output in synchronization with the 1800 MHz to 2500 MHz band. The high frequency signal output from the wide area high frequency tuning unit 120 is second amplified by the secondary high frequency amplifier 130 and then output to the mixer 150.

On the other hand, in the local local oscillator 140, the low-frequency local oscillation circuit 144 by the switching operation by the power supply switching unit 142 and the oscillation switching unit 148 in conjunction with the switching operation of the tuning switching unit 122. The oscillation frequency oscillated at is provided to the mixer 150 or the oscillation frequency oscillated at the high frequency local oscillation circuit unit 146 is provided to the mixer 150.

The low-pass local oscillator circuit 144 is variable in the oscillation range of 1179.5MHz ~ 2278.5MHz, the high-pass local oscillator circuit 146 is variable in the oscillation range of 2279.5MHz ~ 2979.5MHz, which is a phase locked loop (PLL) Since the oscillation frequency is varied by the voltage applied from the circuit unit 190, the local oscillation unit is VC0 whose oscillation frequency is varied according to the strictly applied voltage.

The frequency tuned by the wide area high frequency tuning unit 120 and the oscillation frequency of the wide area local oscillating unit 140 have an intermediate frequency of approximately 480 MHz (exactly 479.5 MHz) in the mixer 150.

The tuning switching unit 122, the power switching unit 142, and the oscillation switching unit 148 have a close correlation with each other, and thus, the switching operation is performed. This means that the low pass tuning filter 124 is selected. In this case, a switching operation is performed such that power is supplied to the low pass local oscillation circuit 144 and the oscillated frequency is provided to the mixer 150, and the high pass local oscillation is performed when the high pass tuning filter 126 is selected. The switching operation is performed such that power is supplied to the circuit 146 and the oscillated frequency is provided to the mixer 150.

Referring to the specific circuit diagrams shown in FIGS. 3 and 4 by the present invention, it can be seen that the tuned high frequency and oscillation frequency are operated to output the same intermediate frequency (approximately 480 MHz).

The mixer 150 outputs an intermediate frequency by mixing the high frequency signal of the secondary high frequency amplifier 130 and the oscillation frequency of the local local oscillator 140, and outputs an intermediate frequency to the primary intermediate frequency amplifier 160. After the first amplified by the intermediate frequency tuning unit 170, the second amplified by the second intermediate frequency amplifier 180 is output to the next step.

As described above, the present invention is to solve the above problems, and can be widely used without limitation according to the low noise converter (LNB) or region, and the tuning band is divided into two bands according to the input high frequency to tune the band. Not only can the gain deviation be greatly reduced, but there is a special effect such that the beat characteristic is improved.

Claims (12)

First and second high frequency amplifiers 110 and 130 for amplifying the high frequency signal induced from the antenna, a mixer 150 for outputting the intermediate frequency signal by mixing the output signal and the oscillation signal of the second high frequency amplifier 130; A first intermediate frequency amplifier 160 for amplifying the output signal of the mixer 150, an intermediate frequency tuner 170 for tuning the output signal of the first intermediate frequency amplifier 160 to an intermediate frequency, and In the satellite broadcasting tuner comprising a second intermediate frequency amplifier 180 for amplifying the output signal of the intermediate frequency modulator 170 and outputs it to the demodulator, the high frequency output from the primary high frequency amplifier 110 A tuning switch 122 for switching a signal, a low pass tuning filter 124 for tuning a high frequency signal switched by the tuning switch 122 to a low frequency band, and the tuning switch 122 High frequency signal switched by Greater high frequency tuning unit 120 including a high-band tuning filter 126 for tuning on; A low frequency local oscillation circuit 144 for oscillating an oscillation frequency corresponding to a high frequency signal output from the low frequency tuning filter 124 of the wide area high frequency tuning unit 120, and a high band for the high frequency tuning unit 120 High frequency local oscillation circuit 146 for oscillating the oscillation frequency corresponding to the high frequency signal output from the tuning filter 126, and two oscillations from the low frequency local oscillation circuit 144 and the high frequency local oscillation circuit 146. A wide region including an oscillation switching unit 148 for switching to correspond to the switching operation of the tuning switching unit 122 of the wide area high frequency tuning unit 120 to provide the oscillation frequency to the mixer 150. Satellite broadcasting tuner for broadband reception, characterized in that it comprises a local oscillator (140). According to claim 1, The tuning switch 122 is connected to the diode (D1) and the diode (D2) in parallel, one side of the anode and the cathode terminal of the diode (D1) and diode (D2) is It is connected to the output terminal of the primary high frequency amplifier 110 through the capacitor C0, and is connected to the power source B1 ⁺ through the resistor R1 and the capacitor C1, and is another power source (B2 ⁺ ). Is connected to the anode terminal of the diode D1 through the resistors R3 and R4, and is connected to the cathode terminal of the diode D2 through the resistors R3 and R5. Credit satellite tuner. The low-pass tuning filter 124 of claim 1 comprises a tuning circuit comprising varactor diodes VD1 and VD2 and condensers C4 and C5, and the diode D1 of the tuning switching section 122. Broadband reception, characterized in that connected to the anode terminal via the coil (L1) and capacitor (C3), and connected to the tuning voltage terminal (Vt) through the resistors (R7, R8) and capacitors (C6, C8). Satellite Broadcast Tuner. The high-pass tuning filter 126 is composed of a stripline-type coil (L2, L3), varactor diodes (VD3, VD4) and condensers (C10, C11), the tuning switching It is connected to the cathode end of the diode D2 of the unit 122 through the coil L4 and the capacitor C9, and is connected to the tuning voltage terminal Vt through the resistors R10 and R8 and the capacitors C12 and C8. Satellite broadcasting tuner for broadband reception, characterized in that the connection is configured. The oscillation switching unit 148 connects the diode D3 and the diode D4 in parallel, and connects one side of the anode terminal and the cathode terminal of the diode D3 and the diode D4. It is connected to the one input terminal of the mixer 150 through the condenser C22, and is connected to the power supply B3 ⁺ through the resistor R21 and the condenser C21, and the other power supply terminal B4 ⁺ is connected. A satellite for broadband reception characterized in that it is connected to the anode end of the diode D3 through R24 and R22 and connected to the cathode end of the diode D4 through resistors R25 and R22. Broadcast tuner. The low-frequency local oscillation circuit 144 includes a resonant circuit composed of a stripline coil L22, a capacitor C29, and varactor diodes VD21 and VD22, and a transistor Q1 and a resistor. An amplification circuit composed of R26 to R29, and the resonant circuit is connected to the phase-locked loop (PLL) circuit section 190 through a resistor R32, and the collector terminals of the transistor Q1 are connected to the capacitors C24 and C26. The satellite broadcasting tuner for broadband reception, characterized in that configured to connect to the anode end of the diode (D3) of the oscillation switching unit 148 through the). The high frequency local oscillation circuit 146 includes a resonant circuit composed of a stripline coil L24, a capacitor C34, and varactor diodes VD23 and VD24, and a transistor Q2 and a resistor (1). An amplification circuit composed of R33 to R36, and the resonance circuit is connected to the phase-locked loop (PLL) circuit section 190 through a resistor R32, and the collector terminals of the transistor Q2 are connected to the capacitors C26 and C31. The satellite broadcasting tuner for broadband reception, characterized in that configured to connect to the anode end of the diode (D3) of the oscillation switching unit 148 through the). The local oscillator 140 of claim 1 corresponds to a switching operation of the oscillation switching unit 148 so as to alternatively provide power to the low frequency local oscillator 144 and the high frequency local oscillator 146. A satellite broadcasting tuner for broadband reception, comprising a switching unit 142 for switching operation 4. The satellite broadcasting tuner for broadband reception according to claim 3, wherein the low pass tuning filter (124) is tuned to 700 MHz to 1700 MHz. 5. The satellite broadcasting tuner for broadband reception according to claim 4, wherein the high pass tuning filter (126) is tuned to 1800 MHz to 2500 MHz. 7. The satellite broadcasting tuner for broadband reception according to claim 6, wherein the low frequency local oscillation circuit (144) has an oscillation range of 1179.5 MHz to 2278.5 MHz. 8. The satellite broadcasting tuner for broadband reception according to claim 7, wherein the high frequency local oscillation circuit (146) has an oscillation range of 2279.5 MHz to 2979.5 MHz.