JP2001197475A - Down converter for private catv system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent an up converter, used for frequency-converting an incoming signal into a private incoming signal at the side of the terminal of a private CATV system, from transmitting a high-frequency noise generated by the operation of an internal circuit to a transmission line inside a building or to the side of terminal equipment. SOLUTION: A shield board 45 is erected in the circumference of a local oscillation circuit 52, an oscillation frequency control circuit 54, a frequency- converting circuit 56, a first amplifier circuit 58, a second amplifier circuit 60 and a filter circuit 62 except a power source circuit 64 on a printed wiring board 50, where various function circuits constituting the up converter are assembled. Moreover, the circuit 52 which is to become the generation source of the high-frequency noise, the circuit 54 and the power source circuit 64 are arranged at positions separated from the filter circuit 62, which is connected to respective terminals T1, T2 and To for inputting/outputting a signal. Then the high-frequency noise generated in the converter infiltrates into the filter circuit 62 or the terminals T1, T2 and To as a result, so that leakage to the outside is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an external bidirectional CA.
In-building CATV that connects the transmission path of the TV system and the terminal terminal in the building to transmit each signal of up and down in both directions
The present invention relates to an up converter used in a system to frequency-convert an upstream signal output from a terminal device into a ridge upstream signal.

[0002]

2. Description of the Related Art Conventionally, a service line from an external two-way CATV system is drawn into a building, and a predetermined frequency band (for example, 70 to 770 MHz) input from the service line is transmitted via a transmission line in the structure. Signal (specifically bidirectional C
(Signal transmitted from the center device of the ATV system)
To the terminal terminal in the building, the upstream signal input from the terminal device on the subscriber side to the terminal terminal to the service line, and output from the service line to the center device side of the bidirectional CATV system. CATV systems are known.

In such an in-building CATV system, noise generated in each part of the building is superimposed on a transmission line via a terminal terminal or the like on a subscriber side, and this is combined with an upstream signal together with an upstream signal. May be output to an external bidirectional CATV system. Therefore, conventionally, in order to reduce ingress noise flowing out to an external two-way CATV system, an upstream signal generated by a subscriber-side terminal device such as a cable modem (specifically, a signal having a lower frequency than a downstream signal) is generated. Using an up-converter, a frequency band (for example, 10 to 55 MHz) that can be transmitted by an external bidirectional CATV system is transmitted to a transmission frequency of a downlink signal (for example, 70 to 55 MHz).
770 MHz) is converted into an in-building upstream signal of a predetermined frequency band (for example, a signal of 821 MHz to 866 MHz) higher than the frequency, transmitted to the service line, and immediately before the upstream signal is output from the transmission line in the building to the service line. It has been considered that the in-building up signal is frequency-converted into an up signal in the original frequency band using a down converter.

[0004]

In an in-building CATV system of this type, an up-converter used to frequency-convert an upstream signal from a terminal device into a building upstream signal is provided by a terminal on each subscriber side. Since the terminal is connected to the terminal, the scale of the CATV system in the building is large, and the number of subscriber-side terminal terminals increases, and the number of up-converters increases.

In a large-scale CATV system having many terminal terminals to which an upconverter is connected, a downconverter provided at a connection point with an external bidirectional CATV system leaks from each upconverter. The problem is that signal components other than the in-building upstream signal become more susceptible to the influence of the signal, and in some cases, the frequency of the in-building upstream signal output from a specific upconverter cannot be converted to the original upstream signal. is there. Less than,
This problem will be described.

First, the up-converter converts the frequency of an up signal output from a terminal device such as a cable modem into an in-building up signal. Therefore, the up converter has a local unit that generates a high-frequency signal for frequency conversion. An oscillation circuit and an oscillation frequency control circuit (for example, a PLL circuit) for controlling the oscillation frequency of the local oscillation circuit to the same frequency as the local oscillation circuit on the down converter side are provided.

[0007] Further, since these circuits are configured using semiconductor elements such as transistors, a constant DC voltage is required as a power supply voltage for stable operation thereof.
For this reason, a power supply circuit (for example, a switching power supply circuit) that normally takes in a 50 Hz or 60 Hz commercial power supply (generally, AC 100 V), converts it into a predetermined DC constant voltage, and supplies it to the above circuits Is provided.

These circuits include a filter circuit for separating or mixing input / output signals (down signal / up signal / up signal in the building) to / from the up-converter according to the frequency band of each signal, and a local circuit. The output from the oscillation circuit and the upstream signal are combined (mixed) and housed in a housing together with a frequency conversion circuit for frequency-converting the upstream signal into a ridge upstream signal.

For this reason, a terminal (hereinafter, referred to as a second terminal) for inputting a down signal and outputting an up signal in the building, which is connected to a terminal terminal of the CATV system in the building, is connected to a terminal in the building after frequency conversion through a filter circuit. In addition to the incoming signal,
A high-frequency signal for frequency conversion generated by the local oscillation circuit, a reference signal used by the oscillation frequency control circuit to control the local oscillation circuit, harmonic components of the reference signal, and generated when the power supply circuit generates a DC constant voltage Various signal components generated in the housing, such as switching noise generated and harmonic components of the switching noise, may enter through the internal space and be output as a noise signal to the terminal terminal together with the in-building up signal.

On the other hand, a terminal device such as a cable modem which outputs an upstream signal to the up-converter transmits and receives data in a time-division manner under the communication control of a communication device provided on the center device side of the external bidirectional CATV system. Therefore, even if there are many terminal devices connected to the transmission line of the CATV system in the building via the terminal terminals and the up-converter, each terminal device does not output an up signal at the same time. A plurality of upconverters connected to the transmission line of the CATV system do not simultaneously output an in-building up signal.

However, in each up-converter, the circuits (local oscillation circuit, oscillation frequency control circuit, power supply circuit, etc.) serving as noise sources always operate as described above, and signal components generated by these circuits are generated. When a signal component (particularly, a signal component having the same frequency as the in-building up signal) intrudes into the second terminal and is transmitted as a noise signal from the second terminal through the terminal terminal of the in-building CATV system to the transmission line, the down signal occurs. A noise signal sent from each upconverter is synthesized and input to the converter.

Therefore, as the number of subscriber terminal terminals increases, the signal level of the noise signal input to the downconverter increases, and the downconverter outputs the noise signal from a specific upconverter by the noise signal. It becomes impossible to convert the frequency of the upstream signal inside the building to the original upstream signal.

The up converter transmits the downstream signal input to the second terminal to a terminal for inputting an upstream signal and outputting a downstream signal (hereinafter referred to as a first terminal). Is also provided, so that the various noise signals described above invade this path,
It may be output to the terminal device together with the downlink signal. If the noise signal output to the terminal device includes a signal component having the same frequency as the downlink signal for data communication transmitted from the communication device on the center device side, the signal component is input to the terminal device. A problem arises in that the downlink signal for data communication is deteriorated, and the terminal device cannot accurately read the downlink signal.

The present invention has been made in view of such a problem, and a signal component generated in an up-converter is
Prevents superimposition as a noise signal on the in-building up signal and down signal output from the up converter,
An object of the present invention is to improve the transmission quality of each signal of uplink and downlink in an ATV system.

[0015]

Means for Solving the Problems and Effects of the Invention A CAT in a building according to claim 1, which has been made to achieve the above object.
For the V system upconverter,
The downstream signal input from the terminal terminal of the V system to the second terminal is transmitted to the first terminal via the filter circuit, and is output from the first terminal to the terminal device on the subscriber side connected thereto. The upstream signal input from the terminal device to the first terminal is transmitted to the frequency conversion circuit via the filter circuit, and is frequency-converted by the frequency conversion circuit into the ridge upstream signal. The frequency-converted in-building upstream signal is transmitted to the second terminal via the filter circuit, and is output from the second terminal to the terminal terminal of the in-building CATV system.

For this reason, the in-building up signal frequency-converted by the up-converter is transmitted between the transmission line and the drop-in line from the external bidirectional CATV system through the terminal terminal and the transmission line of the in-building CATV system. The signal is transmitted to the provided down-converter. The down-converter converts the frequency to the original uplink signal output from the terminal device, and then transmits the signal to an external bidirectional CATV system.

The up-converter includes a local oscillation circuit for generating a high-frequency signal for frequency-converting an upstream signal into a ridge upstream signal by a frequency conversion circuit, similarly to the above-described conventional device, and an oscillation frequency of the local oscillation circuit. An oscillation frequency control circuit that controls a constant frequency using a reference signal having a constant frequency, and generates a DC constant voltage by receiving power supply from a commercial power supply, and generates the DC constant voltage by using a local oscillation circuit and an oscillator. A power supply circuit for supplying the frequency control circuit is provided. The oscillation frequency control circuit is for making the oscillation frequency of the local oscillation circuit coincide with the frequency of the high-frequency signal used when the down converter converts the frequency of the in-building up signal to the up signal.

In the down converter of the present invention, in order to improve productivity, each of the above circuits (namely, a filter circuit, a frequency conversion circuit, a local oscillation circuit, an oscillation frequency control circuit, and a power supply circuit) is connected to one printed wiring. It is formed on a substrate, and is manufactured by housing it in a housing in which the first terminal and the second terminal are assembled.

By the way, when the printed wiring board on which the above circuits are formed is simply housed in a housing,
Due to the shielding effect of the housing, externally generated noise enters the upconverter and the upconverter does not function properly, or various signals generated in the upconverter leak to the outside, Although it is possible to prevent the operation of the case from being affected, various signal components generated by the operation of the active circuits (that is, the local oscillation circuit, the oscillation frequency control circuit, and the power supply circuit) in the up-converter may Through the internal space, the signal may directly enter the second terminal or the first terminal, and may be output from these terminals to the transmission line of the CATV system in the building or to the terminal device side.

Therefore, in the present invention, the first terminal and the second terminal, which are terminals for inputting and outputting a transmission signal to the up-converter, are arranged near the same outer wall surface of the outer wall around the housing, and Inside the body, a filter circuit is formed on one end of the printed circuit board so that the filter circuit is arranged near the wall surface on which the input / output terminals are arranged, and an active circuit (local oscillation circuit) serving as a noise source is formed. , Oscillation frequency control circuit,
The power supply circuit) is formed on the printed circuit board at a position distant from the filter circuit, and the printed circuit board is provided with a high-frequency signal generated by each circuit along the boundary of each circuit. A shield plate is provided upright to prevent the intrusion into other circuits.

Therefore, according to the upconverter of the present invention, various signals generated by the operation of the local oscillation circuit, the oscillation frequency control circuit, and the power supply circuit pass through the internal space of the housing and are connected to the filter circuit and the filter circuit. To the input / output terminals (the first terminal and the second terminal).

Therefore, according to the present invention, it is possible to prevent a noise signal other than a regular in-building up signal, which is obtained by frequency-converting an up signal, from being transmitted from the up converter to the in-building CATV system transmission line. Can be prevented from malfunctioning due to the noise signal. In addition, since it is possible to prevent a noise signal from being sent from the up-converter to the terminal device side, it is possible to prevent the terminal device from being unable to receive and demodulate a downlink signal due to the noise signal.

Therefore, if an in-building CATV system is constructed using the up-converter of the present invention, it is possible to improve the signal transmission quality in the in-building CATV system, and to upgrade to an external bidirectional CATV system. It is also possible to prevent the noise signal generated in the converter from leaking and deteriorating the signal transmission quality in the external system.

From the viewpoint of rationalizing the wiring space or simplifying the wiring work, it is preferable that the transmission line connected to the upconverter be drawn in the same direction from the upconverter. For this purpose, the first terminal and the second terminal may be assembled so as to protrude from the same outer wall surface in the same direction among the outer wall surfaces around the housing.

Here, the up-converter converts the up signal having a lower frequency than the down signal output from the terminal device into:
The frequency is converted into an in-building up signal having a higher frequency than the down signal, and is sent out on the transmission line of the in-building CATV system, and may have only the up signal frequency conversion function. In this case, it is conceivable that the in-building up signal cannot be transmitted to the down converter at the regular signal level.

That is, in the CATV system in the building,
In the transmission line from the up-converter to the down-converter, the signal level of the in-building up signal decreases due to the signal transmission loss, and various devices for branching and distributing the transmission signal are usually provided on the transmission line. Therefore, the signal level of the in-building up signal also decreases due to the passage loss generated when passing through these devices. Further, in order to prevent such a problem, in a CATV system in a building, there is also known a system in which an amplifying device for amplifying a transmission signal bidirectionally is provided upstream (near a down converter) of a transmission line.
When the output level of the in-building up signal from the up-converter is low, it is impossible to input the in-building up signal at a regular level to this amplifier.

Therefore, in the upconverter of the present invention, in addition to the above-described various functional circuits, the printed wiring board further operates by receiving power supply from a power supply circuit. It is preferable to form an amplifier circuit that amplifies the in-building upstream signal frequency-converted by the frequency conversion circuit and outputs the amplified signal to the filter circuit.

That is, if the amplifier circuit is provided in the up-converter, it becomes possible to amplify the frequency-converted in-building up signal to a desired level and to output the amplified signal. It becomes possible to input an in-building up signal at a regular signal level to an amplifying device provided between the up converter and the up converter.

When the amplifier circuit is formed on the printed wiring board in this way, it is necessary to prevent thermal noise or the like generated by the operation of the amplifier circuit from leaking from the input / output terminal to the outside. As described in 3, the shield plate is desirably provided upright at the boundary between the amplifier circuit and the surrounding functional circuits.

Next, in the upconverter of the present invention, each circuit is shielded by arranging a shield plate on the printed circuit board. It is conceivable that a signal generated in the circuit gets over the shield plate and enters the filter circuit or the input / output terminal.

Therefore, in order to solve such a problem and further enhance the shielding effect between the circuits by the shield plate,
According to a fourth aspect of the present invention, among the circuits formed on the printed wiring board, a shield plate is provided so as to individually surround all circuits except for a power supply circuit that needs to take in a commercial power supply using a power supply line or the like. It is preferable to provide a lid on the open end side for shielding each circuit surrounded by the shield plate from above the substrate.

That is, according to this configuration, it is possible to prevent the signal generated in each of the active circuits from crossing the shield plate and entering the filter circuit or the input / output terminal.
Signals generated in the up-converter from the input / output terminals can be more reliably prevented from being output as noise signals.

Next, the first terminal and the second terminal provided as input / output terminals may be directly assembled to the housing. In this case, however, after the printed circuit board is housed in the housing, In addition, the filter circuit formed on the printed circuit board and each terminal must be connected by soldering or the like, and the work of assembling the printed circuit board in the housing becomes complicated.

Therefore, when a shield plate is erected around each circuit except for the power supply circuit as described in claim 4, the shield plate surrounding the filter circuit as described in claim 5 is provided. , I / O terminals are assembled to a shield plate arranged at one end of the printed wiring board along the inner wall of the housing, and when the printed wiring board is stored in the housing, it is pierced on one wall of the housing. It is preferable that the input / output terminal mounted on the shield plate is inserted into the terminal insertion hole so that the input / output terminal is mounted on the housing at the same time when the printed wiring board is mounted in the housing.

In the upconverter of the present invention, at least the first terminal and the second terminal described above are required as the input / output terminals directly or indirectly assembled via the printed wiring board to the housing. , Claim 6
As described in above, in addition to these terminals, an output terminal for outputting the downstream signal input to the second terminal to the terminal device for receiving and demodulating the downstream signal is provided, and the filter circuit is provided in the second terminal. The downstream signal input from the terminal may be distributed to two systems, and the downstream signal after the distribution may be transmitted to the first terminal and the output terminal, respectively.

That is, if the up-converter is configured as described above, by connecting the first terminal to a terminal device such as a cable modem that outputs an up signal, a signal (data communication signal) for the terminal device is transmitted to the terminal device. Down signal and up signal)
Not only can input and output
By connecting to a terminal device for downlink signal reception / demodulation (for example, a TV tuner or a television receiver), a broadcast signal transmitted from an external center device can be transmitted to this terminal device. Become like

Therefore, if this up-converter is used, for example, the subscriber terminal has one terminal, and the subscriber can receive a broadcast signal such as a television broadcast and receive a bidirectional CATV signal.
If you want to enjoy both services of connecting to the Internet using the system, add terminal terminals,
Alternatively, these two services can be enjoyed only by connecting the up-converter to the terminal terminal without connecting the duplexer (so-called separator) for separating the downstream signal to the terminal terminal.

The output terminal may be directly assembled to the housing as in the case of the first terminal and the second terminal, or a shield plate surrounding the periphery of the filter circuit as described in claim 5 above. Of these, it may be assembled to a shield plate arranged at one end of the printed wiring board along the inner wall surface of the housing.

Further, by providing a down converter at the connection point with the external bidirectional CATV system, the in-building upstream signal frequency-converted by the terminal-side up-converter is converted into the original upstream signal to be converted into the external upstream signal. An in-building CATV system configured to be able to transmit to a directional CATV system includes a reference used to control the frequency of the high-frequency signal used by the up-converter and the down-converter in order to match the frequency of the high-frequency signal. It has been considered to make the signal a common signal.

Specifically, an up converter and a down converter are controlled by using a pilot signal of a constant frequency output from a center device as one of downlink signals for adjusting transmission equipment in a bidirectional CATV system.
The reference signal used to control the frequency of the high-frequency signal for frequency conversion may be configured to control the frequency of the high-frequency signal for frequency conversion, or the down-converter may be used to control the frequency of the high-frequency signal for frequency conversion from an external bidirectional CATV system. The signal is transmitted along with the down signal on the transmission line of the CATV system in the building. On the up converter side, the frequency of the high frequency signal for frequency conversion is controlled using the reference signal transmitted from the down converter. And so on.

In order to make the upconverter of the present invention usable in such an in-building CATV system, the down-converted signal inputted from the second terminal is inputted to the filter circuit. A specific signal extraction filter for extracting a specific signal having a constant frequency from among the signals is provided. May be configured to be controlled.

[0042]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram showing the configuration of the entire CATV system in a building according to an embodiment to which the present invention is applied.

As shown in FIG. 1, the CATV in the building according to the present embodiment
The system draws a drop line 6 branched from a transmission line (CATV transmission line) 2 of an external two-way CATV system via a branching device 4 into a building such as an apartment or an apartment via a protector 8, A transmission line L composed of a coaxial cable wired in the building, and a bidirectional amplifier 12, a branch unit 14, and a distributor 16 provided on the transmission line L.
And the like, the down signal (frequency: 70 MHz to 770 MH) of the bidirectional CATV system input from the service line 6
z) is transmitted to a plurality of terminal terminals 18 such as a series unit installed at each subscriber's house in the building,
From the various terminal devices on the subscriber side, an up converter 2 described later
0 to the terminal 18 via the terminal 0
This is transmitted to the service line 6.

In the in-building CATV system according to the present embodiment, the subscriber can enjoy the Internet via the center device of the external two-way CATV system, or can reserve the center device for viewing or paying for a pay program. When transmitting data for shopping or the like, an information terminal device (such as a personal computer) 24 for data communication is connected to the terminal 18 on the subscriber side via an up-converter 20 and a cable modem 22. .

As a result, the transmission data for data communication output from the information terminal device 24 is transmitted by the cable modem 22 to a predetermined frequency band (10 MHz to 55 MHz in this embodiment) which can be transmitted by an external bidirectional CATV system. ), And is converted by the up-converter 20 into a predetermined frequency band (821 in this embodiment).
(MHz to 866 MHz), which is frequency-converted into an in-building upstream signal and input to the terminal 18.

For this reason, the connection between the transmission line L of the in-building CATV system and the drop-in line 6 from the external bidirectional CATV system is connected to the in-building which has been transmitted via the transmission line L from each terminal 18. The upstream signal is sent to an external bidirectional CATV
A down converter 10 is provided for frequency conversion into an original upstream signal that can be transmitted by the system.

The down converter 10 has
A reception signal (frequency: 1035 MHz to 13) from the satellite broadcast receiving BS antenna 28 installed on the rooftop of the building
35 MHz band, hereinafter referred to as a BS-IF signal).
In addition to the downlink signal from the external bidirectional CATV system, the BS-IF signal output from the BS antenna 28 is also transmitted.

In FIG. 1, reference numeral 26 is connected to the terminal 18 to which the upconverter 20 is not connected.
External bidirectional CATV transmitted via transmission line L
Downlink signal from the system or BS from BS antenna 28
-A television receiver that receives an IF signal and demodulates and reproduces a television broadcast of a desired channel.

Next, the configuration of the upconverter 20 used in the in-building CATV system of this embodiment will be described. FIG. 2 is an external view (four views) showing a state of the upconverter 20 viewed from the front, side, back, and bottom, respectively.
Is an exploded perspective view thereof.

As shown in FIG. 2, the upconverter 20 of this embodiment is one in which a printed wiring board 50 on which various circuits described later are mounted is housed in a rectangular housing.
The housing has a vertically long shape when viewed from the front, and its depth is longer than its length in the vertical direction. And
On the front of the housing, a power switch PSW described later is turned ON / O.
A push button 31 for performing FF is provided, and a second terminal T2 for connecting to the terminal terminal 18 via a coaxial cable, and a downstream signal input to the second terminal T2 on the rear surface of the housing in order from the top. Terminal To for directly outputting a BS or IF signal to a television receiver or the like, and a first terminal T1 for connecting to a communication terminal device such as a cable modem 22 that outputs an upstream signal. Have been.

The terminals T1, To and T2 have
An F-type plug is used so that a coaxial cable can be easily connected via an F-type plug. Further, a power outlet 32 is provided below the first terminal T1 on the rear surface of the housing, and a power cord 34 having a power plug 33 at its tip is drawn out from a lower wall surface of the power outlet 32. I have.

On the other hand, a large number of heat radiating holes 35 are formed on the side of the housing of the up-converter 20 to release heat generated by the operation of the internal circuit to the outside. Switches SW1 and SW1 for signal level adjustment described later
Three operation holes 36 for operating SW2 and SW3 from outside are formed. Further, a pair of support portions 37 that support the upconverter 20 are fixed to the bottom surface of the housing at two front and rear positions along the depth direction of the housing.
The support portions 37 project from the side surface of the housing to the left and right, respectively.
Can be prevented from falling sideways.

Next, as shown in FIG. 3, the housing of the up-converter 20 includes an inner case 41 and an outer case 42.
And a front case 43. The inner case 41 has a rectangular plate portion 41a for assembling the printed wiring board 50 in parallel along the side surface of the housing, and an upper end of the four edges of the plate portion 41a excluding the front side of the housing. , Plate portions 41b, 41c standing from the respective edges of the lower end, the rear end,
41d, and the printed wiring board 50 is disposed in a board accommodating portion surrounded by these respective plate portions 41a to 41d. And, in the plate portion 41c at the lower end of the inner case 41,
The above-described three operation holes 36 are formed, and the rear end plate portion 41d is formed.
Are provided with three terminal insertion holes 38 for inserting the above-described terminals T1, T2, and To, a hole 39 for fixing the power outlet 32, and a hole 40 for drawing out the power cord 34, respectively. Have been.

The outer case 42 is different from the inner case 41.
And a plate portion 42a corresponding to the plate portion 41b at the upper end of the inner case 41, and a plate portion extending downward from the left and right edges of the plate portion 42a. 42b and 42c. The above-described heat radiating holes 35 are formed in the respective plate portions 42b and 42c.

For this reason, if the inner case 41 is housed in the outer case 42, a housing having only an open front is formed, and the respective plate portions 42a to 42c of the outer case 42 are formed.
And the lower end plate portion 41c and the rear end plate portion 41d of the inner case 41 form the outer wall of the housing. The inner case 41 and the outer case 42 are respectively
It is formed by pressing a conductive metal plate.

The front case 43 includes the inner case 41.
Board portion 41a for assembling the board and upper and lower plate portions 41b, 41
c, for closing the opening of the housing formed by the outer case 42 and the inner case 41, and the above-described push button 31 is assembled. . The front case 43 is formed of a synthetic resin, and a metal plate for shielding is fixed to an inner wall thereof.

Next, the printed wiring board 50 housed in the housing composed of each of the cases 41 to 43 is made of a double-sided board having a conductive layer formed on the front and back surfaces of an insulating substrate made of synthetic resin. The circuit is formed by forming a circuit pattern and mounting various electronic components on one or both sides thereof.

Then, on the surface side on which various electronic components are mounted, the periphery of each circuit formed on the printed wiring board 50 is surrounded, and a high-frequency signal generated in each circuit passes through the surrounding space to another circuit. Plate 45 to prevent leakage to
Further, a lid 46 for shielding each circuit surrounded by the shield plate 45 from above the substrate is provided on the open end side of the shield plate 45. Also,
A shield lid 47 for preventing unnecessary high-frequency signals from leaking from each circuit pattern is also provided on the back side of the printed wiring board 50. In addition, the shield plate 4
5 and the lids 46 and 47 are formed by pressing a conductive metal plate.

Next, it is formed on the printed wiring board 50,
The configuration and arrangement of each circuit separated by the shield plate 45 will be described with reference to FIG. As shown in FIG. 4, the following functional circuits (1) to (7) are formed on the printed wiring board 50.

(1) A local oscillation circuit 52 for generating a high-frequency signal for frequency-converting an upstream signal into a building upstream signal. (2) An oscillation frequency control circuit 54 for controlling the oscillation frequency of the local oscillation circuit to a constant frequency.

(3) By mixing the upstream signal input to the first terminal T1 from the communication terminal device such as the cable modem 22 with the high frequency signal generated by the local oscillation circuit 52,
A frequency conversion circuit (a so-called mixer) 56 for frequency-converting the upstream signal into a building upstream signal; (4) A first amplifying circuit 58 for amplifying the in-building upstream signal frequency-converted by the frequency converting circuit 56.

(5) A second amplifier circuit 60 for adjusting the signal level for further amplifying the in-building upstream signal amplified by the first amplifier circuit 58 to a predetermined level. (6) The downstream signal input from the terminal 18 to the second terminal T2 is captured and transmitted to the first terminal T1 and the output terminal To, and the upstream signal input to the first terminal T1 is captured. And a signal separating filter circuit 62 for transmitting the in-building up signal output from the second amplifier circuit 60 to the second terminal T2.

(7) An AC power supply (100 V AC) is taken in from an external commercial power supply through a power supply cord 34 to generate a DC constant voltage (for example, 5 V DC) for driving an internal circuit. A power supply circuit 64 composed of a switching regulator that operates these circuits by supplying them to the control circuit 54, the first amplifier circuit 58, the second amplifier circuit 60, and the like.

Here, in the filter circuit 62, the downstream signal including the BS-IF signal input from the terminal 18 to the second terminal T 2 is divided into two by the distribution circuit 71, and of the two divided downlink signals, Is transmitted from the output terminal To directly to an external terminal device (such as a television receiver).

The other downstream signal distributed by the distribution circuit 71 blocks the passage of the upstream signal in the building, and
-In order to pass only a downstream signal that does not include an IF signal, the signal is captured via a low-pass filter (hereinafter, referred to as LPF) 72 whose cut-off frequency is set to, for example, 770 MHz, and thereafter, a branch circuit 73 and a high-pass filter (hereinafter, referred to as LPF) , HPF) 74, and an external communication terminal device (such as the cable modem 22) via the first terminal T1.
Sent to

The HPF 74 is for blocking the passage of the upstream signal input to the first terminal T1 and for passing only the downstream signal, and has a cutoff frequency of, for example, 70M.
Hz. Further, the branch circuit 73 includes an LPF
This is for branching a part of the downstream signal flowing through the downstream signal passing path between the 72-HPF 74, and is constituted by a so-called directional coupler.

The down signal branched by the branch circuit 73 is converted from the down signal by the down converter 1.
0 and the down converter 1 to match the frequency of the high frequency signal used for frequency conversion by the up converter 20.
A reference signal transmitted from 0 is extracted and input to a narrow-band bandpass filter (hereinafter referred to as BPF) 75.

The upstream signal from the communication terminal device input to the first terminal T1 prevents the downstream signal from coming from the HPF 74 and selectively captures only the upstream signal. It is taken in via the LPF 76 set at 55 MHz. And
The upstream signal that has passed through the LPF 76 is input to the frequency conversion circuit 56 via an attenuator (hereinafter, referred to as ATT) 77 for adjusting the signal level.

Next, the in-building up signal output from the second amplifying circuit 60 is amplified by a certain level in the amplifying element 78 and then input to the HPF 79. HPF79,
This is for blocking the passage of the down signal and allowing only the up signal in the building to pass, and the cutoff frequency thereof is set to, for example, 821 MHz. Then, the in-building up signal that has passed through the HPF 79 is transmitted from the connection point between the distribution circuit 71 and the LPF 72 to the second terminal T2 through the distribution circuit, and is transmitted from the second terminal T2 to the terminal terminal 18 (and thus the transmission terminal). (On line L).

On the other hand, the oscillation frequency control circuit 54 transmits the reference signal (specifically, the frequency control reference signal transmitted from the down converter 10) extracted by the BPF 75 on the filter circuit 62 side to the local oscillation circuit 52. And a high-frequency signal for frequency conversion generated by frequency division, respectively, and fetches the signals. The PLL circuit 54 controls the oscillation frequency of the local oscillation circuit 52 so that the phase difference between the divided signals becomes zero.
a and C for controlling the operation of the PLL circuit 54a.
The operation of the PLL circuit 54a makes the oscillation frequency of the local oscillation circuit 52 coincide with the frequency of a high-frequency signal used by the down converter 10 for frequency conversion.

The first amplification circuit 58 converts the frequency-converted in-building upstream signal into a BPF 5
8b, and amplified by the amplifying element 58a, and then output to the second amplifier circuit 60.
The amplifying circuit 60 receives the in-building up signal from the first amplifying circuit 58 via the ATT 60a for adjusting the signal level, amplifies the signal by the amplifying element 60b, and then, via the ATT 60c for adjusting the signal level, the filter circuit. It is configured to output to the amplifying element 78 on the 62 side.

The two ATTs 60 a and 60 c constituting the second amplifying circuit 60 and the ATT 77 provided on the transmission path of the upstream signal from the filter circuit 62 to the frequency conversion circuit 56 are connected to, for example, a PIN diode. The level of the signal passing through the amount of current (in other words, each AT
T attenuation) can be adjusted by an external operation, and each ATT 60a,
Switches SW1, SW2, and SW3 for switching the amount of signal attenuation at 60c and 77 are assembled.

Next, among the various functional circuits configured as described above, the filter circuit 62 is provided near the plate portion 41d at the rear end of the inner case 41 when the printed wiring board 50 is assembled to the inner case 41. The frequency conversion circuit 56, the first amplification circuit 58, and the second amplification circuit 60 are formed so as to be arranged on the rear end side of the printed wiring board 50 so as to be arranged.
Each is formed at a position adjacent to the filter circuit 62 on the printed wiring board 50 inside the filter circuit 62.

The local oscillation circuit 52 for generating a high frequency signal for frequency conversion has a frequency conversion circuit 56
The oscillating frequency control circuit 54 is formed on the printed wiring board 50 on the opposite side of the filter circuit 62, and further includes a local oscillation circuit 52, a first amplifier circuit 58, and a second amplifier circuit 60 on the printed wiring board 50. It is formed at a position adjacent to and farthest from the filter circuit 62.

On the printed wiring board 50, the above-described shield plate 45 is provided except for the power supply circuit 64 so as to prevent unnecessary high-frequency signals generated in the respective circuits from entering other circuits. Each circuit 52, 54, 58,
It is set up so as to surround the formation regions of 60 and 62 respectively. The power supply circuit 64 is formed outside each of the circuit areas surrounded by the shield plate 45 in order to facilitate connection with the power supply cord 34.

In this embodiment, the power supply circuit 64
When the printed wiring board 50 is assembled to the inner case 41, the plate portion 41c at the lower end of the inner case 41 and the shield plate 4
5 and is formed at a position farthest from the filter circuit 62.

The power switch PSW which is turned on / off by the operation of the push button 31 is connected to the printed circuit board 50.
When the front case 43 is assembled to the inner case 41, the push button 31 fixed to one edge of the printed wiring board 50 facing the front case 43 and assembled to the front case 43 By pressing, the power switch PSW can be directly turned on / off via the push button 31.

Next, each of the above ATTs 60a, 60c,
The switches SW1, SW2, and SW3 for level adjustment for switching the amount of attenuation of the 77 are provided when the printed circuit board 50 is assembled to the inner case 41, respectively.
1 and the printed circuit board 5 facing the lower plate portion 41c.
0, and can be operated from the outside via an operation hole 36 formed in the plate portion 41c.

When the printed wiring board 50 is assembled to the inner case 41 of the shield plates 45 erected around the filter circuit 62, the shield plate opposes the plate portion 41d at the rear end of the inner case 41. 45, each terminal T
1, T2, To are provided with plug mounting holes 45a, 45b, 45c for mounting plugs, and each terminal T1, T2, To is connected to the plug mounting holes 45a, 45.
It is directly fixed to the shield plate 45 via b and 45c. Therefore, the printed wiring board 50 is
When assembling, the terminals T1, T2, and To fixed to the shield plate 45 are simply inserted into the three terminal insertion holes 38 formed in the plate portion 41d at the rear end of the inner case 41, respectively. The terminals T1, T2, and To can be made to protrude outside from the rear end of the housing.

As described above, in the upconverter 20 of this embodiment, the terminals T1, T2, To for inputting / outputting signals to / from the upconverter 20 are all concentrated on the rear end side of the housing. The terminals T1, T2, and To use F-type plugs.
Therefore, it is possible to improve the workability when connecting the upconverter 20 to the terminal terminal 18 of the CATV system in the building or to connect to various terminal devices on the subscriber side. The up-converter 20 can be arranged with good appearance while the coaxial cable connected to the up-converter is hidden.

In the up-converter 20, all the various functional circuits constituting the up-converter 20 are formed on a common printed wiring board 50, and all the terminals T1, T2, To are all printed on the printed circuit board 50. Since the functional circuits are fixed in the shield plate 45 erected on the wiring board 50, the storage of each functional circuit in the housing can be performed simply by assembling the printed wiring board 50 to the inner case 41 constituting the housing. As a result, the operability at the time of assembling the upconverter 20 can be improved as compared with a case where each functional circuit is configured separately or each of the terminals T1, T2, and To is assembled to a housing.

The local oscillation circuit 52, the oscillation frequency control circuit 54, and the frequency conversion circuit 5, excluding the power supply circuit 64, among the various functional circuits formed on the printed wiring board 50.
6. A shield plate 45 is provided upright around the first amplifier circuit 58, the second amplifier circuit 60, and the filter circuit 62, and furthermore, a local oscillation circuit 52 which is a source of high frequency noise, an oscillation frequency control The circuit 54 and the power supply circuit 64
Filter circuit 62 connected to each terminal T1, T2, To
The local oscillation circuit 5
2. It is possible to prevent unnecessary high-frequency signals generated by the operation of the oscillation frequency control circuit 54 and the power supply circuit 64 from passing through the surrounding space and entering the filter circuit 62 and the terminals T1, T2, and To. Particularly, in this embodiment, the shield plate 4
5 and the back side of the printed wiring board 50 on which the shield plate 45 is not erected,
47, the filter circuit 62 and the terminals T1,
High-frequency noise can be more reliably prevented from entering T2 and To.

Therefore, the up-converter 20 of the present embodiment
According to this, it is possible to prevent the noise signal from being sent from the up-converter 20 onto the transmission line L of the CATV system in the building, or to prevent the noise signal from being sent from the up-converter 20 to the terminal device side. It is possible to improve the signal transmission quality in the internal CATV system.

The up-converter 20 of this embodiment is
Since the frequency-converted in-building upstream signal is amplified to a desired level and can be transmitted from the second terminal T2 onto the transmission line L, the bidirectional amplifier 1 provided on the transmission line L
2 (and thus the down converter 10) can be supplied with a prescribed level of in-building upstream signal, which can also improve the transmission quality of the in-building upstream signal.

Further, the up-converter 2 of this embodiment
0 indicates that the oscillation frequency of the local oscillation circuit 52 is
a, a reference signal transmitted from the down-converter 10 is extracted, and this is extracted by the PLL circuit 54.
By inputting the signal to a, the PLL circuit 54a controls the oscillation frequency of the local oscillation circuit 52 using the same reference signal as that of the downconverter 10. Therefore, the up-converter 20 can convert the frequency of the upstream signal into a building upstream signal by using a high-frequency signal having the same frequency as that of the down converter 10. The signal can be restored accurately. Therefore, according to the present embodiment, data communication performed between the terminal device on the subscriber side and the center device of the external two-way CATV system can be favorably executed without causing a communication error.

[0086] Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and can take various forms. For example, in the above embodiment, the up converter 20 having the output terminal To for directly outputting the downstream signal or the BS-IF signal to the television receiver or the like has been described, but the present invention includes such an output terminal To. Applicable even for upconverters that are not.

In the above embodiment, the frequency conversion circuit 5
Although the amplifier circuit for amplifying the in-building upstream signal frequency-converted in 6 has been described as having two stages including the first amplifier circuit 58 and the second amplifier circuit 60, what is the number of stages of this amplifier circuit? It may be a step.

[Brief description of the drawings]

FIG. 1 is a configuration diagram illustrating a configuration of an in-building CATV system according to an embodiment.

FIG. 2 is an explanatory diagram illustrating an appearance of an upconverter.

FIG. 3 is an exploded perspective view illustrating a structure of an upconverter.

FIG. 4 is an explanatory diagram showing a circuit configuration of an upconverter and an arrangement of each circuit on a printed wiring board.

[Explanation of symbols]

6 ... drop-in line, 10 ... down converter, 12 ... bidirectional amplifier, 18 ... terminal terminal, 20 ... up converter, 22
... Cable modem, 24 ... Information terminal device, 38 ... Terminal insertion hole, 41 ... Inner case, 42 ... Outer case, 43 ... Front case, 45 ... Shield plate, 46 ... Lid, 50 ... Printed wiring board, 52 ... Local part Oscillation circuit, 54: oscillation frequency control circuit, 56: frequency conversion circuit, 58: first amplifier circuit, 60: second amplifier circuit, 62: filter circuit, 64 ...
Power supply circuit, L: transmission line, T1: first terminal, T2: second terminal, To: output terminal.

Claims (7)

[Claims] 1. A drop line from an external two-way CATV system is drawn into a building, and a down signal of the two-way CATV system input via the drop line is transmitted to a subscriber via a transmission line in the building. A plurality of terminal terminals on the side, and an in-building up signal having a higher frequency than the down signal input from each terminal terminal is transmitted to the drop-in line via the transmission line, and further, the up-building signal is transmitted in the building. An in-building CATV system for converting a signal into an up signal having a lower frequency than the down signal by a down converter provided between the drop-in line and the transmission line, and transmitting the converted signal to the bidirectional CATV system side. In, is provided between the terminal terminal and the terminal device on the subscriber side, from the terminal terminal by frequency-converting the upstream signal output from the terminal device to the in-building upstream signal An upconverter used for transmitting the signal on the transmission line, wherein a first terminal for connecting to the terminal device and a second terminal for connecting to the terminal terminal are used as input / output terminals for the signals. A local oscillation circuit that generates a high-frequency signal for frequency-converting the upstream signal into the ridge upstream signal, and a reference signal having a constant frequency. An oscillation frequency control circuit that controls the frequency to a constant frequency by using the terminal device; and a frequency that frequency-converts an upstream signal input to the first terminal from the terminal device to the in-building upstream signal using a high-frequency signal generated by the local oscillation circuit. A conversion circuit, transmitting the downstream signal input from the second terminal to the first terminal, and transmitting the upstream signal input from the first terminal to the frequency conversion circuit. Further, a filter circuit for signal separation for transmitting the in-building upstream signal frequency-converted by the frequency conversion circuit to the second terminal, and receiving a power supply from a commercial power supply to generate a DC constant voltage, By supplying the generated DC constant voltage to the local oscillation circuit and the oscillation frequency control circuit, a power supply circuit for operating the circuits and a printed circuit board on which various functional circuits including Further, the first terminal and the second terminal protrude from the outer wall surface so as to be disposed near the same outer wall surface among the outer wall surfaces around the housing. When the printed circuit board is housed in the housing, the filter circuit is located near an inner wall surface of the housing where the first terminal and the second terminal protrude to the outside. The local oscillation circuit, the oscillation frequency control circuit, and the power supply circuit are formed at one end side of the printed wiring board, and are formed at a position away from the filter circuit. A shield plate for preventing a high-frequency signal generated in each of the circuits from invading another circuit through a surrounding space is provided upright along a boundary between the circuits. CATV in building
Upconverter for system. 2. The building according to claim 1, wherein the first terminal and the second terminal are assembled so as to protrude in the same direction from the same outer wall surface of the outer wall surface around the housing. Upconverter for CATV system. 3. The printed circuit board operates as the functional circuit by receiving power supply from the power supply circuit,
An amplification circuit is formed to amplify the in-building upstream signal frequency-converted by the frequency conversion circuit and output the amplified signal to the filter circuit. The shield plate is also provided upright at a boundary between the amplification circuit and a peripheral functional circuit. The upconverter for a CATV system in a building according to claim 1 or 2, wherein the upconverter is used. 4. The printed wiring board, wherein the shield plate is erected so as to individually surround all circuits except the power supply circuit among circuits formed on the printed wiring board. A cover for shielding each circuit surrounded by the shield plate from above the substrate is provided on the open end side of the shield plate erected from above. CAT in one of the three listed
Up converter for V system. 5. The terminal provided as an input / output terminal for each signal is disposed at one end of the printed circuit board along an inner wall surface of a housing in a shield plate surrounding a periphery of the filter circuit. When the printed wiring board is housed in the housing, the printed wiring board is inserted into a terminal insertion hole formed in one wall surface of the housing, thereby assembling the printed wiring board into the housing. 5. The upconverter for a CATV system in a building according to claim 4, wherein the upconverter is assembled to the housing at the same time. 6. The casing outputs the downlink signal to a terminal device for downlink signal reception / demodulation in addition to the first terminal and the second terminal as input / output terminals for the signals. The filter circuit distributes the downstream signal input from the second terminal to two systems, and transmits the downstream signal after the distribution to the first terminal and the output terminal, respectively. The upconverter for a CATV system in a building according to any one of claims 1 to 5, wherein the upconverter is configured as follows. 7. The filter circuit is provided with a specific signal extracting filter for extracting a specific signal having a constant frequency from a downstream signal input from the second terminal, and the oscillation frequency control circuit includes: The upconverter for a CATV system in a building according to any one of claims 1 to 6, wherein an oscillation frequency of the local oscillation circuit is controlled using a specific signal extracted by a specific signal extraction filter as the reference signal. .