JP3458939B2 - Tuner for cable modem - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable television, and more particularly to a tuner for cable modem.

[0002]

2. Description of the Related Art An HFC (Hybrid Fiber Co), which is an optical fiber of a trunk network, is used in which a cable television lead-in line to a home is left as a coaxial cable.
ax) Introduction plan is underway. This is a few M per home
Because it is trying to provide a wide band data communication service of bit / second, the state of the art 64QAM has a bandwidth of 6
It is possible to create high speed data lines of MHz and transmission rate of 30 Mbit / sec, for which cable modems are used. Then, it is considered to realize high-speed data communication of 4 Mbits / second to 27 Mbits / second by utilizing an empty channel of the cable television.

A conventional cable modem tuner is shown in FIG.
Shown in. The tuner for the cable modem changes the reception band to
UHF band that receives 470-860 MHz (hereinafter,
A third band), a VHF High band (hereinafter, referred to as a second band) that receives 170 MHz to 470 MHz, and a VHF Lo that receives 54 to 170 MHz.
It is divided into w bands (hereinafter, referred to as a first band) and is composed of a receiving circuit for each band. However, there is currently no uniform regulation on how to divide the reception band.

The CATV signal is an up signal 5 to 42 MH.
z, downlink signals 54 to 860 MHz.
In FIG. 4, the downlink signals 54 to 860 MHz are connected to the cable line from the input terminal 51. On the other hand, the upstream signal 5
At ˜42 MHz, the quadrature phase shift keying (QPSK) data signal from the QPSK transmitter is introduced to the data terminal 91. The data signal is connected to the CATV signal input terminal 51 through the upstream circuit 90.

On the other hand, the downstream signal, after passing through the IF filter 52, enters the input switching circuits 68, 69 and 70, where UH
F BAND, VHF HIGH BAND, and VHF
It can be switched to each circuit of LOW BAND. The IF filter 52 is a bandpass filter including an attenuation band of 5 to 46 MHz and a pass band of 54 MHz or more. Each band is in operation depending on the receiving channel,
Other bands have a function that does not work. For example, U
When receiving a channel in the HF band, the input signal switching circuit 68, the high frequency amplification input tuning circuit 53, the high frequency amplifier 5
6, high frequency amplification output tuning circuit 71, mixing circuit 59, local oscillation circuit 60, IF amplification circuit 92, SAW filter 9
3, the respective functions of the IF amplifier circuit 94 and the PLL channel selection circuit 65 are activated. On the other hand, it is a circuit for other bands,
The input signal switching circuits 69 and 70, the high frequency amplification input tuning circuits 54 and 55, the high frequency amplifiers 57 and 58, the high frequency amplification output tuning circuits 72 and 73, the mixing circuits 61 and 63, and the local oscillation circuits 62 and 64 stop operating. ing.

Next, the operating state of each band will be described. CA
The TV signal passes through the input switching circuits of 68, 69 and 70, then enters the high frequency amplification input tuning circuits 53, 54 and 55, is amplified by the high frequency amplifiers 56, 57 and 58, and then the output tuning circuits 71, 72, and At 73, the received signal is derived. Mixer circuits 59, 61, 63, local oscillator circuits 60, 62,
The signal derived from the high frequency amplifier circuit at 64 is frequency-converted, enters the IF (intermediate) frequency amplifier circuit 92, and is SAW.
After passing through the filter 93, the signal is again amplified by the IF (intermediate) frequency amplifier circuit 94 and led out from the IF output terminal 65. This operation is common to each band. The local oscillator circuits 60, 62, 64 are controlled by a PLL tuning circuit 65.

[0007]

However, the conventional cable modem tuner has the following problems.

1) The cable modem tuner is often applied to a cable television set top box (STB), and therefore the tuner needs a circuit for branching a downstream signal to a QPSK circuit. Here, the set top box (STB) is a device for receiving the signal of the cable television, while the cable modem is for receiving the signal from the cable through the modem when the cable internet is used. This is a modem.

2) The cable modem is a device connected to a personal computer, but the CATV line has been connected to the STB (set top box) until now. Therefore, the cable modem needs a terminal for supplying a signal to the STB.

[0010]

A cable modem tuner according to claim 1 of the present invention branches an upstream circuit for transmitting an upstream data signal to a CATV station and a high frequency signal of the CATV. A branch circuit for supplying to a QPSK demodulation circuit or a set-top box circuit for receiving cable TV, and an attenuation region for removing upstream signals (5
.About.46 MHz) and a pass band of 54 MHz or more I
F filter circuit and multi-wave input received signal according to frequency band, UHF band, VHF high band and VHF
The first and the output to switch to the system with the low band respectively
A second switching circuit, and the RF input tuning circuit for tuning the respective received signal switching output above switching circuit to each desired frequency in each line, each output signal of each RF input tuning circuit in each system A high frequency amplification circuit for amplifying, a high frequency amplification output tuning circuit for tuning the output signal of each high frequency amplification circuit to a desired frequency in each system, and an output of each high frequency amplification output tuning circuit for a desired intermediate frequency in each system a frequency conversion circuit for converting a signal, an intermediate frequency amplifying circuit for amplifying the reception signal frequency-converted by the respective frequency converting circuit
A tuner for a cable modem equipped with the above VHF
High-frequency amplification of high-band and VHF low-band systems
The width input tuning circuit is used for the VHF high band and VHF low band.
First high-frequency amplification input tuning that operates during reception of low band
Circuit and operating state only when receiving the above VHF low band
Is connected in parallel to the above first high frequency amplification input tuning circuit
And a second high frequency amplification input tuning circuit
The above VHF high band and VHF low band strains
The high frequency amplification output tuning circuit of
First high-frequency operation that operates during reception of VHF and VHF low bands
Wave amplification output tuning circuit and when receiving the above VHF low band
Only the first high frequency amplification output tuning circuit is activated.
A second high frequency amplification output tuning circuit connected in parallel to the path
And the second switching circuit and the high frequency amplification circuit.
The VHF high band and the frequency conversion circuit.
It should be shared during reception and reception of the above VHF low band.
And are characterized by.

Further, in the tuner for a cable modem according to a second aspect of the present invention, the branch circuit is arranged before or after the IF filter circuit or between the input terminal and the upstream circuit. It is characterized by.

A tuner for a cable modem according to a third aspect of the present invention is characterized in that the branch circuit comprises a directional coupler or a branch resistor.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention relates to a signal branch in a high frequency input circuit applied to a tuner for a cable modem or the like, and more particularly to a signal branch in a high frequency amplification input tuning circuit of a single conversion type tuner. .

FIG. 1 shows a tuner for a cable modem according to an embodiment of the present invention. This is an invention in which a directional coupler is applied as a branch circuit for branching a high frequency signal of CATV and supplying it to a QPSK demodulation circuit or a set top box circuit for cable television reception, and is arranged in the subsequent stage of the IF filter. This branch circuit 47 is about -3 dB
Although it may be said that there is some loss and the NF (noise figure) in the tuner section deteriorates, the merit that the influence from the input signal switching circuits 18 and 20 can be completely cut off,
Also, the merits are greater, such as the merits of using only one of the high-frequency amplification input tuning circuit 4 or 5 and the high-frequency amplification output tuning circuit 22 or 23, and the merits of sharing the high-frequency amplifier 7.

In the cable modem tuner of the present invention, the reception band is the UHF band (hereinafter referred to as the third band) for receiving 470 to 860 MHz, and 170 MHz to 47 MHz.
It is divided into a VHF High band (hereinafter, referred to as a second band) that receives 0 MHz and a VHF Low band (hereinafter, referred to as a first band) that receives 54 to 170 MHz, and is configured by a reception circuit for each band. Has been done. C
The ATV signal is an upstream signal 5 to 42 MHz, a downstream signal 54
It is operated as ~ 860MHz.

In FIG. 1, the signal (downstream signal 54 to 860 MHz) from the CATV input terminal 1 passes through the IF filter 2 and then enters the directional coupler 47 to be branched. This branch output is derived from the downstream output terminal 46 and connected to the QPSK circuit. Here, the IF filter circuit 2 has a performance including an attenuation range (5-46 MHz) for removing upstream signals and a pass range of 54 MHz or more. On the other hand, the upstream signal (data signal) 5
At ˜42 MHz, the quadrature phase shift keying (QPSK) data signal from the QPSK transmitter is introduced to the data terminal 1. The data signal is connected to the CATV input terminal 1 through the upstream circuit 40.

Next, the main output from the directional coupler 47, which is a branch circuit, is introduced into the input signal switching circuit, and is tuned and amplified by the high frequency amplifier circuit. On the other hand, the downlink signal is I
After passing through the F filter 2, it passes through the directional coupler 47, which is a branch circuit, and enters the input switching circuits 18 and 20, and the UHF
BAND, VHF HIGH BAND and VHFL
It can be switched to two circuits of OW BAND. IF filter 2 is a filter for chromatic attenuation zone 5～46MHz, the pass band of the above 54 MHz. A balun transformer or the like is specifically used for the directional coupler 47 that is a branch circuit, and a resistance branch (coupler) is used as another branch circuit.
And so on. Further, the input switching circuit 18 of the present invention,
20 uses a switching method using a switching diode (SW diode) or a method using a filter by band division.

Next, the operating state of each band will be described. CA
After passing through the IF filter 2, the TV signal passes through the directional coupler 47 and enters the input switching circuit of 18, 20 and B
AND (band) switching is performed, and channel selection is performed by the high frequency amplification input tuning circuits 3, 4, and 5. Next, after being amplified by the high frequency amplifiers 6 and 7, the output tuning circuits 21, 22, and 23
The received signal is derived at. The signals derived from the high frequency amplification circuits in the mixer circuits 9 and 13 and the local oscillation circuits 10, 12 and 14 are frequency-converted, enter the IF (intermediate) frequency amplification circuit 42, and pass through the SAW filter 43, and then again. IF (intermediate) frequency amplification circuit 44 amplifies
It is led to the output terminal 15. This operation is common to each band. In addition, each local oscillation circuit 10, 12, 14
Are controlled by the PLL tuning circuit 45. In the present invention, the mixing circuits 9 and 13 and the local oscillation circuits 10 and 1 are
A circuit including the channels 2 and 14 and the PLL tuning circuit 45 is called a frequency conversion circuit.

Each band is in an operating state according to a receiving channel, and the other bands have a function of not operating. For example, when receiving a channel in the UHF band (third band), the input signal switching circuit 18, the high frequency amplification input tuning circuit 3, the high frequency amplifier 6, the high frequency amplification output tuning circuit 21, the mixing circuit 9, the local oscillation circuit 10, the IF. Amplifier circuit 4
2, SAW filter 43, IF amplifier circuit 44, PLL
Each function of the tuning circuit 45 is in operation. The other circuits are circuits for other bands. Therefore, the operations of the input signal switching circuit 20, the high frequency amplification input tuning circuits 4, 5, the high frequency amplifier 7, the high frequency amplification output tuning circuits 22, 23, the mixing circuit 13, and the local oscillation circuits 12, 14 are stopped.

Similarly, the VHF HIGH BAND (second
Band), 2, 5, 7, 12, 13, 20,
The functions of 23, 40, 42, 43, 44, 45, 40 are in the operating state, 18, 3, 6, 21, 9, 10, 14,
The operation of Nos. 4 and 22 is stopped. VHF LOW BAND
2,20,4,5,7,2 when receiving ( first band )
2, 23, 13, 14, 42, 43, 44, 45, 4
The function of 0 becomes the operating state, and 18, 3, 6, 21,
The operation of 9 and 10 is stopped. This series of operations is sent from the CPU to the PLL tuning circuit 45 as tuning data, and at the same time as channel tuning, the band switching circuits 18 and 20 operate according to the band information, and the power supply switching of each band is switched by this circuit. Is performed to control the operation of the function.

[0021] The operation of the switch 24, 25, 26, the first
It is used by connecting when receiving the band (54 MHz to 170 MHz) . The connection to the high frequency amplification output tuning circuit 22 is
Two switches, switches 25 and 26 are used, which are VHF HIGHBAND and VHF LOW.
It is necessary to break the influence of the tuning coil of BAND.

[0022] By taking the circuit configuration shown in FIG. 1, an input signal switching circuit 20, high frequency amplifier 7, a mixing circuit 1
3 and can be shared in the signal processing of the second band and the first band, and the circuit configuration can be simplified.

That is, in the cable modem tuner according to claim 1, in the switching circuit, the first band ( 54 MHz to 170 MHz), the second band (170 MHz to 470 MHz) and the third band of the received signal ( 470
And a high-frequency amplification input tuning circuit, and a high-frequency amplification output tuning circuit is switched to operate in deriving the switching output. ,.

FIG. 2 shows a tuner for a cable modem according to another embodiment of the present invention. When a branch circuit for branching the high frequency signal of the CATV and supplying it to the QPSK demodulation circuit or the cable television receiving set top box (STB) circuit is arranged between the input terminal which is the preceding stage of the IF filter and the upstream circuit. The invention is mainly suitable for signal supply to STB. A directional coupler (balloon transformer, etc.) is applied to the branch circuit.

In FIG. 2, 1 is a CATV input terminal, 4
9 is a branch circuit for branching a high frequency signal of CATV and supplying it to a QPSK demodulation circuit or a set top box circuit for receiving cable TV, 2 is an IF filter, 18, 2
0 is an input signal switching circuit, 3, 4 and 5 are high frequency amplification input tuning circuits, 6 and 7 are high frequency amplifiers, 21, 22 and 23 are high frequency amplification output tuning circuits, 9 and 13 are mixing circuits, 10,
12 and 14 are local oscillator circuits, 42 is an IF amplifier circuit, and 43.
Is a SAW filter, 44 is an IF amplifier circuit, 45 is a PL
L tuning circuit.

FIG. 3 shows a tuner for a cable modem according to another embodiment of the present invention. This is an invention when a branch circuit for branching a high-frequency signal of CATV and supplying it to a QPSK demodulation circuit or a cable TV receiving set-top box (STB) circuit is arranged in the subsequent stage of the IF filter, and is mainly an inexpensive cable modem. Suitable for tuners. A branch resistance circuit 48 is applied to the branch circuit.

In FIG. 3, 1 is a CATV input terminal, 4
8 is a branch circuit for branching a high frequency signal of CATV and supplying it to a QPSK demodulation circuit or a set top box circuit for receiving cable TV, 2 is an IF filter, 18, 2
0 is an input signal switching circuit, 3, 4 and 5 are high frequency amplification input tuning circuits, 6 and 7 are high frequency amplifiers, 21, 22 and 23 are high frequency amplification output tuning circuits, 9 and 13 are mixing circuits, 10,
12 and 14 are local oscillator circuits, 42 is an IF amplifier circuit, and 43.
Is a SAW filter, 44 is an IF amplifier circuit, 45 is a PL
L tuning circuit.

[0028]

As described above, according to the cable modem tuner of the first aspect of the present invention, the upstream circuit for transmitting the upstream data signal to the CATV station and the CATV high frequency signal. A branch circuit for branching and supplying the signal to a QPSK demodulation circuit or a cable television receiving set-top box circuit, an IF filter circuit including an attenuation range (5-46 MHz) for removing upstream signals and a pass range of 54 MHz or more, Depending on the frequency band, the multi-wave input received signal can be divided into UHF band, VHF high band and
VHF low band switching output to each system
First and second switching circuits, a high frequency amplification input tuning circuit for tuning each received signal switched and output by the above switching circuit to a desired frequency in each system, and an output signal of each high frequency amplification input tuning circuit for each system respectively amplifying in a high frequency amplifier circuit, a high frequency amplifier output tuning circuit for tuning an output signal of each radio frequency amplifier circuit to each desired frequency in each system, outputs desired at each line of each high-frequency amplifier output tuning circuit a frequency conversion circuit for converting the intermediate frequency signal, a cable tuner modem and an intermediate frequency amplifying circuit for amplifying the reception signal frequency-converted by the respective frequency converting circuit, said
The above high of the system of VHF high band and VHF low band
The frequency amplification input tuning circuit has the above VHF high band and V
1st high frequency amplification input that operates when receiving HF low band
Operates only when the force tuning circuit and the above VHF low band are received.
Ready state and parallel to the first high frequency amplification input tuning circuit
And a second high frequency amplification input tuning circuit connected to
Along with the above VHF high band and VHF low band
The high frequency amplification output tuning circuit of the system is the VHF high
Band and VHF low band first operating when receiving
High frequency amplification output tuning circuit and reception of the above VHF low band
The first high-frequency amplification output Chikarado an operational state only when signal
Second high-frequency amplification output tuning circuit connected in parallel with the tuning circuit
And a second switching circuit, the high frequency amplification circuit
Circuit, and the frequency conversion circuit, the VHF high band
Is shared between the reception of VHF and the reception of the above VHF low band.
It is characterized by that.

Therefore, according to the first aspect of the present invention, by having the branch circuit and inserting the branch circuit after the duplexer circuit (the upstream circuit 40 and the IF filter 2), the upstream signal (5 to 42 MHz) can be obtained. ) Can be removed sufficiently.

According to the tuner for cable modem of the second aspect of the present invention, the branch circuit is arranged before or after the IF filter circuit, or between the input terminal and the upstream circuit. It is characterized by that. Therefore, according to the invention of claim 2,
The input signal can be distributed, and the CATV high frequency signal of the input signal can be branched and supplied to the QPSK demodulation circuit or the cable television receiving set-top box circuit.

According to the tuner for cable modem of the third aspect of the present invention, the branch circuit is composed of a directional coupler or a branch resistor, which is economical. A branch circuit can be obtained.

The present invention has the following effects. 1) In the branch circuit, a constant downstream output can be obtained due to the coupling loss of the coupler. 2) The influence of the high frequency amplification input tuning circuit is small. 3) A low loss output is obtained over a high band (54 to 860 MHz). 4) In the branch circuit, a constant downstream output can be obtained with branch loss.

[Brief description of drawings]

FIG. 1 is a tuner for a cable modem according to an embodiment of the present invention, which branches a high frequency signal of CATV to QP.
It is a figure in the case where a directional coupler is applied as a branch circuit for supplying to a SK demodulation circuit or a set top box circuit for cable television reception, and is arranged in the subsequent stage of an IF filter.

FIG. 2 is a diagram showing a tuner for a cable modem according to another embodiment of the present invention, in which a branch circuit is arranged between an input terminal which is a preceding stage of an IF filter and an upstream circuit.

FIG. 3 is a diagram showing a tuner for a cable modem according to another embodiment of the present invention, in which a branch circuit is arranged in a subsequent stage of an IF filter and a branch resistance circuit is applied to the branch circuit.

FIG. 4 is a conventional cable modem tuner.

[Explanation of symbols]

1 CATV input terminal 2 IF filter 3 High frequency amplification input tuning circuit 4 High frequency amplification input tuning circuit 5 High frequency amplification input tuning circuit 6 high frequency amplifier 7 High frequency amplifier 9 mixing circuit 13 Mixed circuit 10 local oscillator 12 Local oscillation circuit 14 Local oscillator circuit 18 Input switching circuit 20 input switching circuit 21 High frequency amplification output tuning circuit 22 High frequency amplification output tuning circuit 23 High frequency amplification output tuning circuit 24 switches 25 switch 26 switch 40 upstream circuit 42 IF amplifier circuit 43 SAW filter 44 IF amplifier circuit 45 PLL tuning circuit 46 Downstream output terminal 47 Branch circuit (directional coupler) 48 branch circuits (branch resistance circuits) 49 branch circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04N 5/38-5/46 H04N ^7/ 14-7/173

Claims (3)

(57) [Claims] 1. An upstream circuit for transmitting an upstream data signal to a CATV station, and a branch for branching a CATV high frequency signal and supplying it to a QPSK demodulation circuit or a cable television receiving set top box circuit. Circuit, an IF filter circuit consisting of an attenuation band (5-46 MHz) for removing upstream signals and a pass band of 54 MHz or more, and a multi-wave input reception signal in a UHF band by a frequency band.
And the system of VHF high band and VHF low band
A first and a second switching circuit for switching and outputting, a high-frequency amplification input tuning circuit for tuning each received signal switched and output by the switching circuit to a desired frequency in each system, and the high-frequency amplification input tuning circuit. a high frequency amplifying circuit for amplifying the respective output signals in each system, a high frequency amplifier output tuning circuit for tuning an output signal of each radio frequency amplifier circuit to each desired frequency in each strain
If, comprising a frequency converter circuit for converting an output of each of the high frequency amplifier output tuning circuit to a signal of a desired intermediate frequency in each system, an intermediate frequency amplifying circuit for amplifying the reception signal frequency-converted by the respective frequency converting circuit Cable modem tu
A chromatography Na, on the system of the VHF high band and VHF low-band
The high frequency amplification input tuning circuit is used for the VHF high band and
And the first high frequency booster that operates when receiving VHF low band
Width input tuning circuit and only when receiving the above VHF low band
Is activated and the first high frequency amplification input tuning circuit
From the second high frequency amplification input tuning circuit connected in parallel
On top of the above, VHF high band and VHF low band systems
The high frequency amplification output tuning circuit is used for the VHF high band and
And the first high frequency booster that operates when receiving VHF low band
Width output tuning circuit and only when receiving the above VHF low band
Is activated and the first high frequency amplification output tuning circuit
From the second high-frequency amplification output tuning circuit connected in parallel
Becomes, the second switching circuit, the high frequency amplifier circuit, and the
When the frequency conversion circuit receives the above VHF high band,
Characterized by sharing with VHF low band reception
A tuner for cable modems. 2. The tuner for a cable modem according to claim 1, wherein the branch circuit is arranged before or after the IF filter circuit, or between the input terminal and the upstream circuit. A tuner for a cable modem. 3. The cable modem tuner according to claim 2, wherein the branch circuit comprises a directional coupler or a branch resistor.