JP4319304B2 - CATV system, down converter, up converter, and amplification device in the building - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention draws a lead-in line from an external two-way CATV system into a building, and transmits downlink signals input from the two-way CATV system to a plurality of terminal devices in the building via a transmission line in the building. In addition, the present invention relates to an in-building CATV system that transmits an upstream signal output from each terminal device to a lead-in line and sends it to an external bidirectional CATV system.
[0002]
[Prior art]
In this type of in-building CATV system, noise generated in each part in the building is superimposed on a transmission line via a terminal terminal on the subscriber side. Of these noises, the same frequency component as that of the upstream signal is output as an inflow noise to the external bidirectional CATV system together with the upstream signal.
[0003]
Therefore, conventionally, in order to reduce inflow noise flowing out to an external bidirectional CATV system, an upstream signal generated by a subscriber-side terminal device such as a cable modem (frequency band that can be transmitted by the bidirectional CATV system ( UHF band (for example, 821 MHz to 866 MHz) that is higher than the original frequency by the up-converter and does not overlap with the transmission frequency of the downstream signal (for example, 70 MHz to 770 MHz). The signal is converted to an upstream signal (hereinafter referred to as an upstream signal), transmitted to the service line, and immediately before the upstream signal is output from the service line to the service line. It is considered to convert to the original frequency (in other words, the upstream signal transmission frequency in the bidirectional CATV system).
[0004]
In this type of in-building CATV system, if the up-converter and the down-converter respectively convert the frequency of each signal using high-frequency signals of different frequencies, the down-converter allows the terminal from the upstream signal in the building. Since the original upstream signal output from the apparatus cannot be restored, it is necessary to match the frequency of the high-frequency signal used for frequency conversion by each converter.
[0005]
For this reason, conventionally, for example, each converter is provided with an oscillator having the same configuration and a small frequency variation, and the oscillation frequency of a local oscillation circuit that generates a high-frequency signal for frequency conversion using a reference signal generated by each oscillator. Or in each converter, the oscillation frequency of a local oscillation circuit that generates a high-frequency signal for frequency conversion is used to adjust the level of a downstream signal in a common reference signal (for example, in a bidirectional CATV system) It is conceived that control is performed using a pilot signal or the like having a constant frequency flowing in the transmission line.
[0006]
That is, if the up-converter and the down-converter each perform frequency conversion of each signal using high-frequency signals having the same frequency, the original upstream signal before the up-converter performs frequency conversion in the down-converter. Can be accurately restored, and the upstream signal output from the terminal device on each subscriber side can be sent as it is from the in-building CATV system to the external bidirectional CATV system.
[0007]
[Problems to be solved by the invention]
However, when the present inventor conducted an experiment, when the above-mentioned in-building CATV system was actually constructed, in the large-scale in-building CATV system with a large number of up-converters, the original upstream signal was accurately restored on the down-converter side. It turns out that there are cases where it is not possible. And in order to clarify this problem, when this inventor performed various experiments, the following thing was understood.
[0008]
That is, first, when an upstream signal of 10 MHz to 55 MHz is frequency-converted into an in-building upstream signal of 821 MHz to 866 MHz by an up-converter, the in-building upstream signal is converted to the original frequency band (10 MHz by the down converter. Frequency conversion to an upstream signal (˜55 MHz), the frequency of the high-frequency signal used to frequency-convert each signal by the up-converter and the down-converter may be set to 811 MHz or 876 MHz.
[0009]
In this case, the upstream signal has a lower frequency than the downstream signal, and the upstream signal in the building has a higher frequency than the downstream signal. Therefore, the frequency of the high-frequency signal for frequency conversion does not affect the downstream signal. As described above, it is general to set the frequency (876 MHz) higher than the downlink signal or the uplink signal in the building.
[0010]
When the frequency of the high-frequency signal for frequency conversion is set in this way, the high-frequency signal used for frequency conversion in the up-converter is close to the frequency of the up-signal in the building. It was found that a high-frequency signal for frequency conversion leaked on the transmission line along with the upstream signal in the building.
[0011]
On the other hand, in an in-building CATV system, an up-converter is installed for each terminal device that outputs an upstream signal, so that the number of subscribers who own such terminal devices increases (in other words, the in-building CATV system). The larger the scale of the signal), the greater the number of high frequency signals that leak from the upconverter onto the transmission line.
[0012]
In contrast, each up-converter performs data communication in a time-sharing manner with a communication device provided in the center device of the external bidirectional CATV system. The converter does not output the building up signal at the same time.
[0013]
As a result, high-frequency signals leaking from each up-converter are synthesized on the transmission line and input to the down-converter. The input level increases as the scale of the in-building CATV system increases. It turned out that it becomes larger than the input level of the signal.
[0014]
In addition, the high-frequency signal input to the down converter via the transmission line in this way is the phase difference when the high-frequency signal leaking from each up-converter is synthesized on the transmission line, and the high-frequency signal for each up-converter. It has also been found that a noise component (hereinafter referred to as phase noise) having a spread in the upper and lower frequency directions around the normal frequency (876 MHz) is included due to a slight frequency shift or the like.
[0015]
Next, as described above, when a high-frequency signal used for frequency conversion on the up-converter side (specifically, a synthesized signal thereof) is input to the down-converter together with the in-building upstream signal, the high-frequency signal is transmitted within the down-converter. And the in-building upstream signal are input to a frequency conversion circuit (generally a mixer) and synthesized with the high-frequency signal generated in the down converter.
[0016]
Therefore, in the down converter, although the in-building upstream signal is frequency-converted to the original upstream signal by the high-frequency signal generated in the down converter, it is also a high-frequency signal including phase noise transmitted together from the terminal side. As a result of the synthesis, the upstream signal after frequency conversion is given phase noise having a spread in the upper and lower frequency directions, and particularly in a large CATV system, the upstream signal is buried in the surrounding phase noise. It turns out that there is.
[0017]
In addition, in order to solve such a problem, by adjusting the phase of the high-frequency signal generated on each up-converter side, or by adjusting the line length of the transmission line from each up-converter to the junction point of the high-frequency signal, Although the high-frequency signals leaking from each up-converter may cancel each other on the transmission line, it is difficult to actually take such measures.
[0018]
The present invention has been made in view of such problems. On the terminal side, an up-converter is used to frequency-convert an upstream signal into a high-in-building upstream signal, and on the service line side connected to an external bidirectional CATV system. In an in-building CATV system that uses a down converter to frequency-convert the upstream signal in the building to the original upstream signal, the down converter is affected by the influence of the high-frequency signal for frequency conversion leaked from the up-converter on the terminal side. It is an object of the present invention to make it possible to accurately restore the original upstream signal without receiving it.
[0019]
[Means for Solving the Problems and Effects of the Invention]
In the in-building CATV system according to claim 1, which has been made to achieve the above object, a downlink signal input from an external bi-directional CATV system through a lead-in line as in the conventional in-building CATV system described above. In addition to transmitting to a plurality of terminal terminals via a transmission line in the building, the in-building upstream signal input from the terminal device on the subscriber side to each terminal terminal via the up-converter is a lead-in line via the transmission line. From the service line to the external bidirectional CATV system, a down converter provided between the service line and the service line is used to convert the upstream signal in the building into the original upstream signal output by the terminal device. The upstream signal is transmitted.
[0020]
In the building CATV system according to the present invention, the down converter can accurately convert the up signal in the building into the original up signal without being affected by the high frequency signal for frequency conversion leaking from the up converter. In order to eliminate the high-frequency signal of the specific frequency that the up-converter used to convert the upstream signal to the upstream signal on the transmission path of the upstream signal from the up-converter to the down-converter. A trap circuit is provided.
[0021]
For this reason, according to the in-building CATV system of the present invention, the above-described phase noise generated by synthesizing on the transmission line the high-frequency signal for frequency conversion leaked on the transmission line from the up-converter connected to each terminal terminal. Is added to the upstream signal after frequency conversion by the down converter, and this is transmitted to an external bidirectional CATV system, and the down converter accurately restores the original upstream signal, The upstream signal can be transmitted to an external bidirectional CATV system without degrading the quality of the upstream signal.
[0022]
In this case, the trap circuit includes a transmission line from the down converter to each terminal, a passage path for the upstream signal in the building in the transmission equipment provided on the transmission line, and the up converter It may be provided in at least one of the output path of the upstream signal in the building and the input path of the upstream signal in the down converter.
[0023]
Of these, if the device is provided independently on the transmission line of the in-building CATV system as a device independent of other transmission devices, the number of transmission devices provided on the transmission line increases, so the trap circuit For example, it may be incorporated in various transmission devices such as an amplifying device, a branching device, and a distributing device provided on a transmission line from the down converter to each terminal, or may be incorporated in the up converter or the down converter. .
[0024]
That is, if the trap circuit is built in the transmission device, down converter or up converter in this way, it is not necessary to separately connect a dedicated device as the trap circuit on the transmission line, so that the in-building CATV of the present invention can be used. The construction cost for constructing the system can be reduced.
[0025]
The trap circuit is for removing a high-frequency signal for frequency conversion leaking from the up-converter on the terminal side, and can be configured by using a so-called resonance circuit. If it is difficult to completely remove the trap signal, trap circuits may be provided at a plurality of locations on the transmission path of the upstream signal in the building. A device (a transmission device such as an amplifying device, an up converter, a down converter, etc.) having a built-in trap circuit may be used.
[0026]
In addition, when the trap circuit is built in the transmission device, up-converter, or down-converter in this way, the transmission of the upstream signal in the building in these devices is prevented from passing downstream signals, etc. Since a filter circuit (such as a bandpass filter) for allowing only the upstream signal to pass is provided, the trap circuit is affected by the filter circuit, and the resonance circuit constituting the trap circuit is routed to the upstream upstream signal transmission path. When an inductive reactance is used or a capacitive reactance is used, the attenuation change characteristic in the vicinity of the frequency of the high-frequency signal to be removed by the trap circuit differs.
[0027]
Specifically, when a parallel resonance circuit is connected to the transmission path of the upstream signal using the inductive reactance, the series resonance is caused by the series resonance of the capacitive component of the parallel resonance circuit and the inductive reactance. The signal component corresponding to the resonance frequency will be attenuated. If such a trap circuit is provided on the transmission path for the upstream signal in the building together with the filter circuit for passing the upstream signal, such as a bandpass filter, the trap circuit. In the frequency characteristics, the attenuation amount sharply increases on the low frequency side centering on the series resonance frequency, but the attenuation amount does not change sharply on the high frequency side.
[0028]
Conversely, when a parallel resonant circuit is connected to the transmission path of the upstream signal using the capacitive reactance, the series resonance occurs due to the series resonance of the inductive component of the parallel resonant circuit and the capacitive reactance. The signal component corresponding to the resonance frequency will be attenuated. If such a trap circuit is provided on the transmission path for the upstream signal in the building together with the filter circuit for passing the upstream signal, such as a bandpass filter, the trap circuit. In the frequency characteristics, the attenuation amount sharply increases on the high frequency side with the series resonance frequency as the center, but the attenuation amount does not change sharply on the low frequency side.
[0029]
For this reason, in the building CATV system, the high-frequency signal for frequency conversion is set to a higher frequency than the upstream signal in the building, and the trap circuit is built in the transmission device, up-converter, or down-converter. In this case, it is desirable to configure the trap circuit by connecting the resonance circuit to the in-building upstream signal transmission path via the inductive reactance as described in claim 3. If the high-frequency signal is set to a frequency lower than the in-building upstream signal and the trap circuit is built in the transmission device, up-converter, or down-converter, as in claim 4 The trap circuit is preferably configured by connecting the resonant circuit to the in-building upstream signal transmission path through the capacitive reactance.
[0030]
In other words, in this way, the attenuation amount of the signal generated in the trap circuit can be changed abruptly on the upstream signal side in the building around the frequency of the high frequency signal for frequency conversion, and the upstream signal in the building is trapped. Loss caused by passing through the circuit can be minimized.
[0031]
On the other hand, even if the trap circuit is configured as described in claim 3 or claim 4, depending on the frequency difference between the in-building upstream signal and the high frequency signal for frequency conversion and the resonance characteristic “Q” of the trap circuit. When the in-building upstream signal passes through the trap circuit, the frequency characteristics of the in-building upstream signal may be affected.
[0032]
That is, for example, as described above, in a system that converts an upstream signal of 10 MHz to 55 MHz to an upstream signal of 821 MHz to 866 MHz by an upconverter, the frequency conversion high frequency signal usually has a frequency of 876 MHz. In addition to this signal, a signal having a frequency of 811 MHz can be used.
[0033]
Accordingly, in such a system, a signal component of 866 MHz or less (or 821 MHz or more) is passed through the trap circuit for removing the high frequency signal without loss, and a sufficient high frequency signal of 876 MHz (or 811 MHz) is sufficient (for example, several tens of dB or more). It is necessary to use an extremely high “Q” resonant circuit that can be reduced.
[0034]
However, in order to increase the “Q” of the trap circuit, it is necessary to use a resonance element (coil, capacitor, etc.) having a high “Q”, which increases the size of the trap circuit. There is a problem that the cost increases.
On the other hand, if the trap circuit is to be realized at low cost using a general-purpose coil or capacitor that can be downsized, the “Q” of the trap circuit becomes low and the so-called frequency cut becomes worse. The upstream signal in the building is attenuated on the side close to the frequency of the high frequency signal for frequency conversion within the transmission band of the upstream signal (in other words, the high frequency side or the low frequency side in the transmission band of the upstream signal in the building). Problems will arise.
[0035]
In this way, when a transmission loss occurs in the frequency band of the in-building upstream signal when the in-building upstream signal passes through the trap circuit, the frequency converter leaked from the up converter in the down converter Even if the in-building upstream signal can be frequency-converted to the upstream signal without being affected by the high-frequency signal, the upstream signal after the frequency conversion will be transmitted on the high-frequency side or the low-frequency side due to the in-band transmission loss caused by the trap circuit The signal level becomes low, and it becomes impossible to send an upstream signal having normal characteristics to the external bidirectional CATV system.
[0036]
Therefore, in order to be able to use a general trap circuit having a relatively low “Q” as a trap circuit and that can be realized at low cost, the inside of the ridge from the up converter to the down converter as described in claim 5 can be used. It is preferable to provide an equalizer for compensating for the in-band transmission loss of the in-building upstream signal caused by the in-building upstream signal passing through the trap circuit on the upstream signal or the upstream signal transmission path.
[0037]
In other words, in this way, the in-band transmission loss caused by the in-building upstream signal passing through the trap circuit is compensated by the equalizer, and is output from each terminal device to the external bidirectional CATV system from the down converter. The upstream signal can be transmitted at a desired level in the entire band.
[0038]
The equalizer compensates for in-band transmission loss on the high-frequency side or low-frequency side of the in-building upstream signal caused by the in-building upstream signal passing through the trap circuit, and the upstream signal sent to the external CATV system is compensated for. Since the signal level is for preventing the signal level from becoming lower on the high-frequency side or low-frequency side of the upstream signal, the upstream upstream signal transmission path in which the trap circuit is provided (specifically, as described in claim 6) Is the transmission line from the down converter to each terminal, the passage path of the upstream signal in the building in the transmission equipment provided on the transmission line, the output path of the upstream signal in the up converter, the interior of the down converter (Upstream signal output path) or an upstream signal input path in the upconverter or upstream signal output path in the downconverter. It may be provided in the transmission path of the signal.
[0039]
A signal processing circuit such as an equalizer is easier to design if the frequency of the signal to be corrected is lower, and the equalizer is installed on the upstream signal transmission path even if it is the upstream upstream signal transmission path. More preferably, the equalizer is connected to an upstream signal transmission path (an upstream signal input path in the up converter and an upstream signal output path in the down converter) having a frequency lower than that of the upstream signal in the building. It is advisable to provide it.
[0040]
As with the trap circuit, the equalizer is also used for various transmissions such as an up converter, a down converter, or an amplification device, a branch device, a distribution device, etc. provided on the transmission line rather than being configured as a single device on the transmission line. It should be built into the device. In addition, if one equalizer cannot compensate for the in-band transmission loss of the in-building upstream signal caused by the in-building upstream signal passing through the trap circuit, the in-building upstream signal in the in-building CATV system can be compensated. Alternatively, a plurality of upstream signal transmission paths may be provided.
[0041]
Next, the down converter according to claim 7 is for constructing the in-building CATV system according to any one of claims 1 to 6, and is connected via a lead-in line via the first downstream signal passing path. A downstream signal input from an external bidirectional CATV system on the terminal side transmission line, and at the first frequency conversion means, the upstream signal transmitted from the up converter via the transmission line by the first frequency conversion means; By mixing the high-frequency signal generated by the first high-frequency signal generating means, the in-building upstream signal is frequency-converted to the upstream signal, and the upstream signal after the frequency conversion is converted to the incoming line side (in other words, external bidirectional CATV). To the system side).
[0042]
In the down converter of the present invention, the high-frequency signal (in other words, the first high-frequency signal generation) used by the up-converter on the terminal side on the input path of the in-building upstream signal to the first frequency conversion means is used. A trap circuit for removing a signal having the same frequency as the high frequency signal generated by the means is provided.
[0043]
Therefore, according to the down converter of the present invention, the high-frequency signals for frequency conversion leaking from the plurality of up-converters on the terminal side are combined on the transmission line, and the combined high-frequency signals are transmitted from the transmission line to the inside of the building. Even if it is input together with the signal, the trap circuit reduces the high-frequency signal (specifically, the above-described high-frequency signal including phase noise) input to the first frequency conversion means, and the first frequency conversion means reduces the signal in the building. Thus, the original upstream signal can be accurately restored.
[0044]
On the other hand, the down converter according to claim 8 is for constructing the in-building CATV system according to claim 5 or claim 6, and, similarly to the down converter according to claim 7, the first downstream signal passing path. The down signal inputted from the external bidirectional CATV system via the lead-in line is sent to the transmission line on the terminal side via the lead-in line and transmitted from the up converter via the transmission line by the first frequency conversion means. The upstream signal in the building is mixed with the high-frequency signal generated by the first high-frequency signal generating means, so that the upstream signal in the building is frequency-converted into the upstream signal, and the upstream signal after the frequency conversion is converted to the incoming line side (in other words, Then, the data is sent to the external bidirectional CATV system side.
[0045]
In the down converter of the present invention, the in-building up signal is present in at least one of the input path of the in-building up signal to the first frequency converting means and the output path of the up signal from the first frequency converting means. An equalizer is provided to compensate for in-band transmission loss caused by passing through the trap circuit.
[0046]
Therefore, according to the down converter of the present invention, the ridge provided with the trap circuit for removing the high-frequency signal for frequency conversion leaked from each up-converter on the terminal side on the transmission path of the upstream signal in the ridge In the internal CATV system, when the upstream signal in the building passes through the trap circuit, even if the signal level on the frequency side close to the high frequency signal for frequency conversion of the upstream signal in the building is reduced due to transmission loss in the trap circuit, Upstream signals can be sent to the external bidirectional CATV system at the normal level of the entire band.
[0047]
Next, the up converter according to claim 9 is for constructing the in-building CATV system according to any one of claims 1 to 6, and is transmitted to the terminal terminal via the down converter and the transmission line. A downstream signal from the external bidirectional CATV system that has been transmitted to the terminal device side via the second downstream signal passing path, and an upstream signal output from the terminal device by the second frequency conversion means; 2 By mixing the high frequency signal generated by the high frequency signal generating means, the upstream signal is frequency-converted into an in-building upstream signal, and the in-building upstream signal after the frequency conversion is converted to the terminal terminal side (in other words, the in-building CATV system). On the transmission line).
[0048]
In the up-converter of the present invention, the high-frequency signal generated by the second high-frequency signal generating means (in other words, the down converter is used for frequency conversion on the output path of the in-building upstream signal from the second frequency converting means. A trap circuit for removing a signal having the same frequency as the high-frequency signal to be transmitted).
[0049]
Therefore, according to the up-converter of the present invention, it is possible to prevent the high-frequency signal used for frequency conversion of the upstream signal to the in-building upstream signal from leaking onto the transmission line of the in-building CATV system. It is possible to prevent the original upstream signal from being normally restored due to the influence of the leaked high frequency signal.
[0050]
On the other hand, the up-converter according to claim 10 is for constructing the in-building CATV system according to claim 5 or 6, and, similar to the up-converter according to claim 9, a down converter and a transmission line are provided. The downlink signal from the external bidirectional CATV system that has been transmitted to the terminal terminal via the second downlink signal passing path is sent to the terminal apparatus side and output from the terminal apparatus by the second frequency conversion means. The upstream signal and the high-frequency signal generated by the second high-frequency signal generating means are mixed to frequency-convert the upstream signal into an in-building upstream signal, and the in-building upstream signal after the frequency conversion is converted to the terminal terminal side ( In other words, it is sent to the transmission line of the in-building CATV system.
[0051]
In the up-converter of the present invention, the in-building upstream signal is present in at least one of the upstream signal input path to the second frequency converting means and the in-building upstream signal output path from the second frequency converting means. An equalizer is provided to compensate for in-band transmission loss caused by passing through the trap circuit.
[0052]
Therefore, according to the up-converter of the present invention, the ridge provided with the trap circuit for removing the high-frequency signal for frequency conversion leaking from each up-converter on the terminal side on the transmission path of the upstream signal in the ridge In the internal CATV system, when the in-building upstream signal output from the up-converter passes through the trap circuit, the signal level on the frequency side close to the high-frequency signal for frequency conversion of the in-building upstream signal due to transmission loss in the trap circuit Even if the signal drops, the upstream signal can be transmitted from the down converter to the external bidirectional CATV system at the normal level of the entire band.
[0053]
The first high frequency signal generating means constituting the down converter according to claim 7 or 8 and the second high frequency signal generating means constituting the up converter according to claim 9 or 10 have the same frequency. As described above, when the first and second high-frequency signal generating means generate high-frequency signals of different frequencies, the original upstream signal output from the terminal device by the down converter is generated. It is because it becomes impossible to restore.
[0054]
In order to enable the first and second high-frequency signal generating means to generate high-frequency signals having the same frequency as described above, the high-frequency signal generating means of each converter is used as in the conventional in-building CATV system described above. An oscillator for generating a reference signal with a small frequency fluctuation (for example, a crystal oscillator), a frequency variable type local oscillation circuit for generating a high-frequency signal for frequency conversion, and a local oscillation circuit using a reference signal generated by the oscillator And a control circuit (for example, a PLL circuit) for controlling the oscillation frequency of the converter, and the reference signal generating oscillators provided in each converter have the same configuration, or the high-frequency signal generating means of each converter is a bidirectional CATV. A signal with a constant frequency included in the downlink signal, such as a pilot signal used to adjust the level of the downlink signal in the system, is extracted as a reference signal. A reference signal extraction circuit (for example, a bandpass filter), a frequency variable type local oscillation circuit that generates a high-frequency signal for frequency conversion, and a local oscillation circuit using the reference signal extracted by the reference signal extraction circuit What is necessary is just to comprise from the control circuit (for example, PLL circuit) which controls this oscillation frequency.
[0055]
Further, in such a conventional technology, each converter must be provided with an expensive oscillator made of a crystal oscillator or the like as an oscillator for generating a reference signal. When a specific signal such as a pilot signal is not transmitted from the bidirectional CATV system, there is a problem that the frequency of the high frequency signal used for frequency conversion in each converter cannot be matched. An oscillator for generating a reference signal is provided on the transmission line or in the down converter, and the reference signal is transmitted from the oscillator to the transmission line, so that each converter uses the reference signal generated by the oscillator to oscillate the local oscillation circuit. The frequency may be controlled.
[0056]
Next, an amplifying device according to claim 11 is for constructing an in-building CATV system according to any one of claims 1 to 6. The amplifying apparatus is provided on a transmission line from the down converter to each terminal terminal on the subscriber side as one of the transmission devices, and the downstream signal transmitted from the down converter side is passed through the third downstream signal passage. Routed on the transmission line on the terminal side via the path, and the in-building upstream signal transmitted from the up converter via the transmission line on the terminal side is transmitted to the down converter side via the in-building upstream signal passing path. Send out on the transmission line. Further, at least one of the third downlink signal passage route and the in-building upstream signal passage route is provided with a signal amplifying means for amplifying the downstream signal or the upstream signal flowing through the route, and further, the in-building upstream signal passage route. Above, a trap circuit for removing a high-frequency signal for frequency conversion leaking from the terminal-side up-converter is provided.
[0057]
Therefore, according to the amplifying apparatus of the present invention, it is possible not only to amplify at least one of the down signal and the up signal in the building to a predetermined level on the transmission line of the in-building CATV system, It becomes possible to reduce the high-frequency signal for frequency conversion leaking from the converter, and it is possible for the down converter to restore the original upstream signal normally from the upstream signal in the building.
[0058]
On the other hand, an amplification device according to a twelfth aspect is for constructing an in-building CATV system according to the fifth or sixth aspect. And this amplifying device sends out the downlink signal transmitted from the down converter side onto the transmission line on the terminal side via the third downlink signal passing path, as in the amplifying device according to claim 11, and The in-building upstream signal transmitted from the up-converter via the transmission line on the side is sent to the transmission line on the down-converter side via the upstream signal passing path in the building, and the downstream signal passing path and the upstream in the building are transmitted. The signal amplifying means provided on at least one of the signal passing paths amplifies the down signal flowing in the path or the up signal in the building.
[0059]
According to the amplifying device of the present invention, as in the amplifying device according to claim 11, in-band transmission caused by the in-building upstream signal passing through the trap circuit on the in-building upstream signal passing path. An equalizer is provided to compensate for the loss.
For this reason, in the amplifying apparatus of the present invention, not only can the at least one of the down signal and the up signal in the building be amplified to a predetermined level on the transmission line of the in-building CATV system, but also the building of the in-building CATV system. The signal level on the frequency side close to the high-frequency signal for frequency conversion of the upstream signal in the building due to transmission loss in the trap circuit when the upstream signal in the building passes through the trap circuit provided on the transmission path of the upstream signal Even if the signal drops, the upstream signal can be transmitted from the down converter to the external bidirectional CATV system at the normal level of the entire band.
[0060]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a configuration diagram showing the overall configuration of an in-building CATV system according to an embodiment to which the present invention is applied.
[0061]
As shown in FIG. 1, the in-building CATV system of this embodiment is configured to connect a lead-in line 6 branched from an external bidirectional CATV system transmission line (CATV transmission line) 2 via a branching device 4 via a protector 8. In addition, a transmission line L made of a coaxial cable drawn into a building such as an apartment or an apartment and wired in the building, and a bidirectional amplifier 12, a branching device 14, a distributor provided in the transmission line L A plurality of terminal terminals 18 composed of serial units or the like installed at each subscriber's house in the building are used for the downlink signal (frequency: 70 MHz to 770 MHz) of the bidirectional CATV system input from the lead-in line 6 through 16 or the like. In addition, the in-building upstream signal inputted to the terminal terminal 18 from various terminal devices on the subscriber side via the up-converter 20 described later is transmitted to the lead-in line 6. The bidirectional amplifier 12 corresponds to the amplification device of the present invention.
[0062]
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 make reservations for pay programs and TV shopping for the center device. When transmitting data for this purpose, an information terminal device (such as a personal computer) 24 for data communication is connected to the terminal terminal 18 on the subscriber side via the up converter 20 and the cable modem 22.
[0063]
As a result, the transmission data for data communication output from the information terminal device 24 is transmitted in a predetermined frequency band (10 MHz to 55 MHz in the present embodiment) that can be transmitted by the cable modem 22 using the external bidirectional CATV system. The up-converted signal is further converted into an in-building upstream signal in a predetermined frequency band (821 MHz to 866 MHz in this embodiment) by the up-converter 20 and input to the terminal 18.
[0064]
For this reason, the in-building upstream signal transmitted from each terminal 18 via the transmission line L is connected to the connection portion between the transmission line L of the in-building CATV system and the lead-in line 6 from the external bidirectional CATV system. A down converter 10 is provided for frequency conversion to an original upstream signal that can be transmitted by an external bidirectional CATV system.
[0065]
In FIG. 1, reference numeral 26 is connected to a terminal 18 to which the up-converter 20 is not connected, receives a downstream signal transmitted from the external bidirectional CATV system transmitted via the transmission line L, and receives a desired channel. Represents a TV receiver that demodulates and plays back TV broadcasts.
[0066]
Next, the configuration of the down converter 10 and the up converter 20 used in the in-building CATV system of this embodiment will be described with reference to FIG.
[Down converter]
As shown in FIG. 2A, the down converter 10 is connected to an external connection terminal T1 for connecting a lead-in line 6 from an external bidirectional CATV system and a transmission line L in the building 10. An internal connection terminal T2 is provided.
[0067]
The downstream signal input to the external connection terminal T1 is taken into the down converter 10 through a high-pass filter (hereinafter referred to as HPF) 31, and is mixed with the mixing circuit 32 and the low-pass filter (hereinafter referred to as LPF). ) 33 and the internal connection terminal T2.
[0068]
Here, the HPF 31 is for passing a downstream signal and blocking the passage of the upstream signal after frequency conversion, and the cutoff frequency is set to 70 MHz, for example. The LPF 33 is for passing a downstream signal and blocking the passage of the upstream signal input to the internal connection terminal T2 via the transmission line L. The cutoff frequency is set to 770 MHz, for example. Yes. Therefore, in the down converter 10 of the present embodiment, the first downlink signal passing path of the present invention is formed by the HPF 31 and the LPF 33.
[0069]
Also, the mixing circuit 32 provided on the downlink signal passing path between the HPF 31 and the LPF 33 mixes the reference signal described later with the downlink signal passing through this path, so that the reference signal is mixed with the downlink signal on the terminal side. The transmission line L is a so-called directional coupler.
[0070]
Next, the in-building upstream signal from the terminal input to the internal connection terminal T2 is taken into the up-converter 20 via the HPF 34. The HPF 34 is for preventing the downstream signal output from the LPF 33 from wrapping around and selectively capturing only the upstream signal in the building, and the cutoff frequency is set to 821 MHz, for example.
[0071]
The in-building upstream signal taken into the down converter 10 via the HPF 34 is an attenuator for signal level adjustment (a so-called attenuator, hereinafter referred to as ATT) 35 and a band-pass filter (hereinafter referred to as BPF). Input to the amplifying circuit 37. The BPF 36 is used to selectively pass the upstream signal in the building, and the signal pass band is set to the transmission frequency (821 MHz to 866 MHz) of the upstream signal in the building.
[0072]
The in-building upstream signal input to the amplifier circuit 37 is amplified to a predetermined level by the amplifier circuit 37 and then input to the mixer 38 as the first frequency conversion means. The mixer 38 mixes the high-frequency signal from the frequency variable type local oscillation circuit 40 whose oscillation frequency is controlled to be constant (876 MHz in this embodiment) by the PLL circuit 39 and the in-building upstream signal. The in-building upstream signal is frequency-converted to the original upstream signal before the up-converter 20 performs frequency conversion.
[0073]
Here, the PLL circuit 39 divides and takes in the high-frequency signal for frequency conversion output from the local oscillation circuit 40 and the reference signal so that the phase difference between the divided signals becomes zero. By controlling the oscillation frequency of the local oscillation circuit 40, the high-frequency signal for frequency conversion in the down converter 10 is controlled to a constant frequency corresponding to the reference signal. In this embodiment, the reference signal used by the PLL circuit 39 to control the oscillation frequency of the local oscillation circuit 40 is generated by the reference oscillation circuit 41 in the down converter 10. Therefore, in this embodiment, the PLL circuit 39, the local oscillation circuit 40, and the reference oscillation circuit 41 function as the first high-frequency signal generating means of the present invention.
[0074]
The oscillation frequency of the reference oscillation circuit 41 is set to a frequency lower than that of the downstream signal. The reference signal output from the reference oscillation circuit 41 and having a frequency lower than that of the downstream signal is the PLL circuit as described above. In addition to the signal 39, the signal is input to the above-described mixing circuit 32 via the narrow band BPF 42 that selectively allows the reference signal to pass through. As a result, the reference signal is mixed with the downstream signal by the mixing circuit 32 as described above, and then sent out onto the transmission line L via the LPF 33 and the internal connection terminal T2.
[0075]
Note that the reference signal is transmitted from the internal connection terminal T2 to the transmission line L in this way by transmitting the reference signal to each up-converter 20 on the terminal side, This is because a high-frequency signal for frequency conversion can be generated using the same reference signal. That is, in this embodiment, by transmitting the reference signal from the down converter 10 to each up-converter 20 on the terminal side, the frequency of the high-frequency signal used for frequency conversion by each up-converter 20 is used by the down-converter 10 for frequency conversion. It matches the high frequency signal.
[0076]
Next, the upstream signal frequency-converted by the mixer 38 is transmitted through the BPF 43 whose signal pass band is set to the upstream signal transmission frequency (10 MHz to 55 MHz) in order to selectively pass the upstream signal. The signal is input to the amplification circuit 44 for amplification. The upstream signal is amplified to a predetermined level by the amplifier circuit 44, and then sent to the lead-in line 6 via the signal level adjusting ATT 45, LPF 46, and external connection terminal T1. The LPF 46 is for blocking the passage of the downstream signal input to the external connection terminal T1 and allowing only the upstream signal after the frequency conversion to pass, and the cut-off frequency is set to 55 MHz, for example. .
[0077]
Next, in the down converter 10 of this embodiment, the input path of the in-building upstream signal from the internal connection terminal T2 to the mixer 38 (specifically, the path between the ATT 35 and the BPF 36) A trap circuit (hereinafter referred to as TRP) 71 for removing a high-frequency signal for frequency conversion on the up-converter 20 side leaked from the up-converter 20 and transmitted to the down-converter 10 through the transmission line L Is provided.
[0078]
As shown in FIG. 3A, the TRP 71 is composed of a parallel circuit of a coil L1 and a capacitor C1, and a parallel resonance circuit in which the resonance frequency is set to a frequency lower than the high-frequency signal for frequency conversion, and the parallel resonance circuit. The coil L2 is connected to a ground path having the same potential as that of the outer conductor of the coaxial cable constituting the transmission line L. Equivalent to reactance).
[0079]
The TRP 71 performs series resonance at a constant frequency determined by the inductive reactance of the coil L2 and the capacitance component of the parallel resonance circuit, so that the series resonance frequency matches the frequency of the high-frequency signal for frequency conversion. The high-frequency signal for frequency conversion that flows through the passage route of the upstream signal in the building is removed.
[0080]
As described above, in this embodiment, the TRP 71 uses a so-called L-coupled trap circuit in which a parallel resonant circuit including a coil L1 and a capacitor C1 is connected to a passage path of an upstream signal through the coil L2. However, in this L-coupled trap circuit, the frequency characteristic of the trap circuit is shown in FIG. 3 (b) by connecting to the BPF 36 for passing the upstream signal in the wing provided in the down converter 10. In this way, with respect to the frequency of the signal to be removed (resonance frequency at which the attenuation amount is maximum in the figure), the fall of the attenuation amount on the side where the frequency is low becomes steep, and the signal for the in-building upstream signal lower than this resonance frequency This is because the influence can be reduced.
[0081]
Furthermore, in the down converter 10 of the present embodiment, an equalizer (hereinafter referred to as EQ) is provided in the output path of the upstream signal from the mixer 38 to the external connection terminal T1 (specifically, the path between the BPF 43 and the amplifier circuit 44). ) 76 is provided. The EQ 76 is for compensating for in-band transmission loss that occurs when the in-building upstream signal passes through the TRP 71, and is configured, for example, as shown in FIG.
[0082]
That is, as shown in FIG. 4A, the EQ 76 is connected in parallel to a series circuit of a pair of resistors Ro having the same resistance value connected in series to the passage path of the upstream signal and the two resistors Ro. The resistor R1, the series resonance circuit composed of the capacitor C11 and the coil L11 connected in parallel to the series circuit of the two resistors Ro, and the resistor R2 having one end connected to the connection point of the two resistors Ro. And a parallel resonance circuit comprising a capacitor C12 and a coil L12 provided between the other end of the resistor R2 and the ground.
[0083]
The EQ 76 sets the resistance value of the pair of resistors Ro to a resistance value (for example, 75Ω) corresponding to the transmission impedance of the signal in the system, and sets the resistance values of the resistors R1 and R2 as appropriate. The resistor Ro, the resistor R1, and the resistor R2 are made to function as an attenuation circuit (attenuator) having a constant attenuation amount, and the capacitances of the capacitors C11 and C12 and the inductances of the coils L11 and L12 constituting each resonance circuit are respectively It is a well-known one set so that “ωL11 = 1 / ωC12” and “ωL12 = 1 / ωC11”.
[0084]
Therefore, in this EQ 76, as shown in FIG. 4B, for a signal of a specific frequency, the impedance of the series resonant circuit is “0” and the impedance of the parallel resonant circuit is “maximum”. For a signal of any other frequency, the impedance of the series resonant circuit is “maximum” and the impedance of the parallel resonant circuit is “0”, and the signal is attenuated by the attenuation circuit. It can be attenuated with a certain amount of attenuation determined by the characteristics and passed.
[0085]
In this embodiment, the resistors R1 and R2 are configured using variable resistors so that the attenuation amount by the attenuation circuit can be adjusted as appropriate. That is, in the EQ 76 of the present embodiment, when the resistance Ro is set to 75Ω corresponding to the transmission impedance of the system signal, for example, if the resistance values of the resistors R1 and R2 are set to the same 75Ω, the attenuation amount is 6 dB. If R1 = 32.5Ω and R2 = 150Ω, the attenuation circuit has an attenuation of 3 dB. EQ76 is within the bandwidth of the in-building upstream signal generated when the in-building upstream signal passes through TRP71. Since the transmission loss is compensated, the frequency characteristic of EQ76 can be finely adjusted according to the frequency characteristic of TRP71.
[0086]
The frequency of the signal at which the impedance of the series resonance circuit is “0” is set to the frequency after frequency conversion corresponding to the maximum frequency 866 MHz of the uplink signal in the building (in other words, the minimum frequency of the uplink signal is 10 MHz). Yes.
That is, the down converter 10 of this embodiment is transmitted from the terminal side together with the in-building upstream signal only by providing the BPF 36 on the passage path of the in-building upstream signal, for example, as shown by a solid line (BPF) in FIG. Since the high-frequency signal for frequency conversion (the 876 MHz signal) cannot be sufficiently removed, a TRP 71 for removing the high-frequency signal is provided on the passage path of the in-building upstream signal. This TRP 71 is shown in FIG. When the general trap circuit shown in (a) is used, the attenuation characteristic on the lower frequency side than the resonance frequency of the TRP 71 cannot be made steep, and the in-building upstream signal is shown by a dotted line (BPF + TRP) in FIG. As shown in FIG. 2, the signal is attenuated on the high frequency side of the transmission band.
[0087]
Therefore, in this embodiment, as shown by a one-dot chain line (BPF + TRP + EQ) in FIG. An EQ 76 is provided on the upstream signal path.
[0088]
For this reason, the impedance of the series resonant circuit is “0” so that EQ76 can increase the signal level on the low frequency side (10 MHz side) of the upstream signal corresponding to the high frequency side (866 MHz side) of the upstream signal in the building. Thus, the frequency of the signal that can be passed without being attenuated is set to the minimum frequency 10 MHz of the upstream signal after frequency conversion corresponding to the maximum frequency 866 MHz of the upstream signal in the building.
[Upconverter]
As shown in FIG. 2B, the up-converter 20 is connected to the first connection terminal T3 for connection to the terminal terminal 18 via a coaxial cable or the like, and the cable modem 22 or the like that outputs an upstream signal. And a second connection terminal T4 for connecting to the terminal device.
[0089]
The downlink signal input from the terminal terminal 18 to the first connection terminal T3 is taken into the up-converter 20 via the LPF 51, and is communicated via the branch circuit 52, the HPF 53, and the second connection terminal T4. It is sent to the device side.
Here, the LPF 51 is for blocking the passage of the upstream signal in the building after the frequency conversion and allowing only the downstream signal input to the first connection terminal T3 to pass, and the cutoff frequency is set to 770 MHz, for example. ing. The HPF 53 is for blocking the passage of the uplink signal input from the communication terminal device to the second connection terminal T4 and allowing only the downlink signal to pass, and the cut-off frequency is set to 70 MHz, for example. . Therefore, in the upconverter 20 of this embodiment, the LPF 51 and the HPF 53 form the second downlink signal passage path of the present invention.
[0090]
A branch circuit 52 provided on a downstream signal passing path between the LPF 51 and the HPF 53 is for branching a part of the downstream signal passing through this path, and is a so-called directional coupler. It is configured. The downstream signal branched by the branch circuit 52 is input to a narrowband BPF 60 for extracting the reference signal transmitted from the down converter 10.
[0091]
Next, the uplink signal from the communication terminal device input to the second connection terminal T4 is taken into the upconverter 20 via the LPF 54. The LPF 54 is for preventing the downstream signal output from the HPF 53 from wrapping around and selectively capturing only the upstream signal, and the cutoff frequency is set to 55 MHz, for example.
[0092]
The upstream signal taken into the up-converter 20 via the LPF 54 is input to the mixer 57 as the second frequency conversion means via the ATT 56 for signal level adjustment. Then, the mixer 57 mixes the high frequency signal from the frequency variable type local oscillation circuit 59 whose oscillation frequency is controlled to be constant (876 MHz in this embodiment) by the PLL circuit 58 and the upstream signal. The frequency of the signal is converted to an upstream signal in the building.
[0093]
Here, the PLL circuit 58 uses the reference signal extracted by the BPF 60 (in other words, the reference signal transmitted from the down converter 10) and the high-frequency signal for frequency conversion output from the local oscillation circuit 59, Each frequency-divided high frequency signal in the up-converter 20 is controlled by controlling the oscillation frequency of the local oscillation circuit 59 so that the phase difference of each frequency-divided signal becomes zero. This is for controlling to the same constant frequency as the high-frequency signal for frequency conversion on the down converter 10 side. Therefore, in this embodiment, the branch circuit 52, the BPF 60, the PLL circuit 58, and the local oscillation circuit 59 function as the second high-frequency signal generating means of the present invention.
[0094]
Next, the in-building upstream signal frequency-converted by the mixer 57 is a BPF 61 in which the signal pass band is set to the transmission frequency (821 MHz to 866 MHz) of the in-building upstream signal in order to selectively pass the in-building upstream signal. Is input to the amplifying circuit 62 for amplifying the upstream signal in the building. The building up signal is amplified to a predetermined level by the amplifying circuit 62 and then transmitted to the terminal terminal 18 (and thus transmitted through the signal level adjusting ATT 63, HPF 64, and the first connection terminal T3). Sent to the line L) side. The HPF 64 is for blocking the passage of the downlink signal input to the first connection terminal T3 and allowing only the in-building uplink signal after the frequency conversion to pass, and its cutoff frequency is set to 821 MHz, for example. Has been.
[0095]
Furthermore, in the up-converter 20 of the present embodiment, the output path (specifically, the path between the BPF 61 and the amplifier circuit 62) of the in-building upstream signal from the mixer 57 to the first connection terminal T3 is a local part. In order to prevent the high-frequency signal for frequency conversion output from the oscillation circuit 59 from being sent from the first connection terminal to the transmission line L through the output path of the in-building upstream signal, a trap for high-frequency signal removal A circuit (TRP) 72 is provided. The TRP 72 is configured as shown in FIG. 3A, similar to the TRP 71 provided in the down converter 10.
[0096]
Further, in the up-converter 20 of the present embodiment, the upstream signal input path from the second connection terminal T4 to the mixer 57 (specifically, the path between the LPF 54 and the ATT 56) is a ridge after frequency conversion. An EQ 78 is provided to compensate for in-band transmission loss that occurs when the inbound signal passes through the TRP 72. The EQ 78 is configured as shown in FIG. 4A, like the EQ 76 provided in the down converter 10.
[0097]
As described above, in the in-building CATV system of this embodiment, the upstream signal having a frequency lower than that of the downstream signal is frequency-converted into the upstream signal having a frequency higher than that of the downstream signal, so that transmission within the building is performed. Trap circuits (TRP) 71 and 72 for removing high-frequency signals used for frequency conversion on the up-converter 20 side are provided on the up-converter 20 and the down-converter 10 used for transmitting the line L in the upstream direction, respectively. Provided.
[0098]
For this reason, it is possible to prevent (reduce) the transmission of high-frequency signals for frequency conversion from the up-converters 20 connected to the terminal terminals 18 on the subscriber side onto the transmission line L, and to leak from the up-converters 20. It is possible to prevent (reduce) that the output high frequency signal for frequency conversion is synthesized and input to the mixer 57 of the down converter 10.
[0099]
Therefore, according to the present embodiment, the above-described phase noise generated when the high-frequency signal for frequency conversion leaked onto the transmission line L from the up-converter 20 connected to each terminal 18 is synthesized on the transmission line. It is added to the upstream signal after the frequency conversion by the down converter 10, and it can be prevented that this is transmitted to the external bidirectional CATV system.
[0100]
In the in-building CATV system of the present embodiment, the down converter 10 and the up converter 20 use the down converter 10 to compensate for the in-band transmission loss that occurs when the in-building up signal passes through the TRP 71 and TRP 72, respectively. EQ76 and EQ78 are provided in the upstream signal output path and the upstream signal input path in the up-converter 20, respectively.
[0101]
For this reason, according to the in-building CATV system of the present embodiment, when the in-building up signal passes through the trap circuit (TRP 71, 72) in the in-building CATV system, the down converter 10 transfers to the external bidirectional CATV system. It is also possible to prevent the signal level on the low frequency side of the transmitted upstream signal from being lowered.
[0102]
Therefore, according to the in-building CATV system of the present embodiment, the down converter 10 accurately restores the original upstream signal from the in-building upstream signal, and reduces both the outside without reducing the quality of the upstream signal. It becomes possible to send to the counter CATV system.
[0103]
In particular, in the present embodiment, EQ76 and EQ78 are provided not on the in-building upstream signal but on the upstream signal passing path having a frequency lower than this to correct the transmission characteristics of the upstream signal. Therefore, the operating frequencies of the EQs 76 and 78 can be set low, and the design and manufacture can be easily performed as compared with the case where the in-building upstream signal is corrected.
[0104]
As mentioned above, although one Example of this invention was described, this invention is not limited to the said Example, A various aspect can be taken.
For example, in the above embodiment, the trap circuit is incorporated in both the down converter 10 and the up converter 20, but other transmission devices (specifically, bidirectional amplifiers) provided on the transmission line L are described. 12, a branching device 14, a distributor 16, etc.) may be incorporated.
[0105]
Therefore, a case where a trap circuit is built in the bidirectional amplifier 12 will be described as another embodiment of the present invention.
FIG. 6 is a block diagram showing the configuration of the bidirectional amplifier 12.
The bidirectional amplifier 12 corresponds to the amplifying device of the present invention, and includes an input terminal T5 connected to the internal connection terminal T2 of the down converter 10 via the transmission line L, and a terminal side more than the bidirectional amplifier 12. And an output terminal T6 for connection to the transmission line L.
[0106]
The downstream signal input from the internal connection terminal T2 of the down converter 10 to the input terminal T5 via the transmission line L is taken into the bidirectional amplifier 12 via the LPF 81. Downstream signals that have passed through the LPF 81 are an input stage amplification circuit 82, a gain adjustment circuit (hereinafter referred to as GC) 83, a middle stage amplification circuit 84, a tilt circuit (hereinafter referred to as TLT) 85, and an output. By sequentially passing through the stage amplification circuit 86, the signal is amplified to a predetermined level. Thereafter, the data is sent out on the transmission line L on the terminal side via the LPF 87 and the output terminal T6.
[0107]
The LPF 81 and the LPF 87 are for blocking the passage of the upstream signal in the building and allowing only the downstream signal to pass, and the cutoff frequency is set to 770 MHz, for example. For this reason, in the bidirectional amplifier 12 of the present embodiment, a third downstream signal passing path is formed by the two LPFs 81 and 87.
[0108]
Further, the GC 83 provided on the third downstream signal passing path together with the three amplifier circuits 82, 84, 86 functioning as the downstream signal amplifier means that the downstream signal output from the amplifier circuit 86 at the output stage has a predetermined level. By adjusting the attenuation amount of the built-in variable attenuator, the overall amplification factor of the downlink signal amplification system is automatically adjusted. The TLT 85 is an attenuation characteristic of the downlink signal on the transmission line L. In response to this, the level of the downstream signal output from the output terminal T6 is adjusted so that the signal level increases as the frequency increases.
[0109]
On the other hand, the in-building upstream signal input from the terminal-side transmission line L to the output terminal T6 is taken into the bidirectional amplifier 12 via the HPF 88. The downstream signal that has passed through the HPF 88 passes through the input stage amplifier circuit 89, GC90, the output stage amplifier circuit 91, and the ATT 92 in order, and is amplified to a predetermined level. Then, it is sent out onto the transmission line L on the down converter 10 side.
[0110]
The HPF 88 and the HPF 93 are for blocking the passage of the downstream signal and allowing only the upstream signal in the building to pass, and the cutoff frequency is set to 821 MHz, for example. For this reason, in the bidirectional amplifier 12 of this embodiment, the two HPFs 88 and 93 form the in-building upstream signal passing path of the present invention. Further, in the bidirectional amplifier 12 of the present embodiment, the two amplifier circuits 89 and 91 provided in the passage route of the in-building upstream signal formed by the HPFs 88 and 93 function as the in-building upstream signal amplification means of the present invention. .
[0111]
Then, on the passage route of the in-building upstream signal formed by the HPFs 88 and 93 in this way (specifically, the route between the HPF 88 and the amplifier circuit 89 of the input stage), the up-converter 20 on the terminal side A trap circuit (TRP) 73 is provided for removing the high-frequency signal for frequency conversion leaked on the transmission line before being amplified by the amplifier circuit 89 in the input stage. The TRP 73 is configured as shown in FIG. 3A, similarly to the TRPs 71 and 72 described above.
[0112]
In the bidirectional amplifier 12 of the present embodiment configured as described above, the downstream signal flowing in the transmission line L and the upstream signal in the building can be amplified to a predetermined level, and each up-converter 20 on the terminal side can be amplified. It is possible to remove (reduce) the high-frequency signal for frequency conversion leaking from
[0113]
For this reason, even if the bidirectional amplifier 12 of this embodiment is provided on the transmission line L of the in-building CATV system, the high-frequency signal for frequency conversion leaked from each up-converter 20 on the terminal side is transmitted on the transmission line L. Thus, it is possible to restore the original upstream signal normally from the in-building upstream signal to the down converter.
[0114]
Further, if an in-building CATV system is constructed using the down converter 10 and the up converter 20 shown in FIG. 2 and the bidirectional amplifier 12 shown in FIG. It is possible to more reliably prevent the composite signal of the high frequency signal from being transmitted to the mixer of the down converter 10.
[0115]
When the TRP 73 is provided in the bidirectional amplifier 12 as described above, the in-band transmission loss generated when the in-building upstream signal passes through the TRP 73 is compensated for on the passage path of the in-building upstream signal. An equalizer may be provided. In this case, an equalizer having the same configuration as the EQs 76 and 78 incorporated in the down converter 10 and the up converter 20 shown in FIG. 2 may be used. Therefore, it is necessary to set the operating frequency of the equalizer to the frequency (866 MHz) on the high frequency side of the in-building upstream signal.
[0116]
In the above embodiment, the trap circuit (TRP) 71, 72 is described as being used as shown in FIG. 3A. However, as this trap circuit, for example, as shown in FIG. The coil L3 is connected in series to the passage path for the upstream signal in the building, and the coil L4 is coupled to the coil L3 by mutual induction (M coupling) via a magnetic material made of ferrite or the like. The capacitor C2 may be connected in parallel to L4, and one end thereof may be grounded to the ground.
[0117]
That is, even if such an M-coupled trap circuit is configured, a parallel resonant circuit is configured by the coil L4 and the capacitor C2 connected in parallel to each other. If it is set to the frequency of the high frequency signal for use, the high frequency signal for frequency conversion induced in the coil L4 via the coil L3 can be efficiently removed.
[0118]
However, in order to configure the trap circuit in this way, it is necessary to use a transformer in which the coil L3 and the coil L4 are wound around a common core made of ferrite or the like, compared with that shown in FIG. Since the size of the trap circuit becomes large, it is conceivable that when these are incorporated in the down converter 10 or the up converter 20 as in the above embodiment, the size of each of these converters is increased. Therefore, it is desirable that the trap circuit shown in FIG. 7 is configured as a dedicated device that is incorporated in a predetermined housing and connected in series to the transmission line L, for example.
[0119]
In the above embodiment, the high-frequency signal for frequency conversion is described as being used as a high-frequency signal having a frequency higher than that of the in-building upstream signal. It is also possible to use a high-frequency signal having a lower frequency (specifically, a signal having a frequency of 811 MHz).
[0120]
In this case, since the trap circuit (TRP) needs to remove the high-frequency signal on the lower frequency side than the in-building upstream signal, the trap circuit (TRP) has the frequency of the signal to be removed (in other words, If this is the case, the attenuation of the attenuation on the higher frequency side becomes steep compared to the resonance frequency at which the attenuation becomes maximum), and the influence on the signal in the building higher than this resonance frequency can be reduced. It is desirable.
[0121]
For this purpose, for example, as shown in FIG. 8, a parallel resonant circuit comprising a coil L1 and a capacitor C1 is added to the trap circuit (TRP), and the capacitor C3 (corresponding to the capacitive reactance described in claim 4). ), A so-called C-coupled trap circuit connected to the passage route of the in-building upstream signal may be used. As shown in FIG. 8B, the frequency characteristic of the C-coupled trap circuit is higher on the higher frequency side than the frequency of the signal to be removed (resonance frequency at which the attenuation is maximum in the figure). This is because the fall of the amount of attenuation becomes steep.
[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 a block diagram illustrating a configuration of a down converter and an up converter provided with a trap circuit.
FIG. 3 is an explanatory diagram showing the configuration of a trap circuit and its frequency characteristics.
FIG. 4 is an explanatory diagram showing the configuration of an equalizer and its frequency characteristics.
FIG. 5 is an explanatory diagram illustrating operations of a trap circuit and an equalizer.
FIG. 6 is a block diagram showing a configuration of a bidirectional amplifier provided with a trap circuit.
FIG. 7 is an explanatory diagram showing a configuration of a trap circuit (M coupling).
FIG. 8 is an explanatory diagram showing the configuration of a trap circuit (C coupling) and its frequency characteristics.
[Explanation of symbols]
6 ... service line, 10 ... down converter, 12 ... bidirectional amplifier, 18 ... terminal terminal, 20 ... up converter, 22 ... cable modem, 24 ... information terminal device, 31, 34, 53, 64, 88, 93 ... HPF ( High pass filter), 32... Mixing circuit, 33, 46, 51, 54, 81, 87... LPF (Low pass filter), 35, 45, 56, 63, 92... ATT (Attenuator), 36, 43, 42, 60 , 61 ... BPF (band pass filter), 37, 44, 62, 82, 84, 86, 89, 91 ... amplifier circuit, 38, 57 ... mixer, 39, 58 ... PLL circuit, 40, 59 ... local oscillation circuit, 41 ... reference oscillation circuit, 52 ... branch circuit, 71, 72, 73 ... TRP (trap circuit), 76, 78 ... EQ (equalizer) 83, 90 ... GC (gain adjustment circuit), 85 ... LT (tilt circuit).

Claims (12)

A lead-in line from an external bidirectional CATV system is drawn into the building, and a downlink signal input from the lead-in line is transmitted to a plurality of terminal terminals in the building through the transmission line in the building.
Transmitting the ridge upstream signal having a frequency higher than that of the downstream signal input to each terminal terminal from the terminal device on the subscriber side through the up converter, to the service line via the transmission line,
Furthermore, the down converter provided between the transmission line and the lead-in line outputs the in-building upstream signal from the terminal device, and the frequency is lower than that of the downstream signal before the up converter performs frequency conversion. It is configured to frequency-convert to a low original upstream signal and send it on the lead-in line,
Moreover, in the in-building CATV system in which the up-converter and the down-converter respectively convert the frequency of the upstream signal or the upstream signal in the building using a high-frequency signal having the same frequency,
To remove a high-frequency signal having a specific frequency used by the up-converter to frequency-convert the upstream signal to the upstream signal on the transmission path of the upstream signal from the up-converter to the down-converter. An in-building CATV system characterized by providing a trap circuit. The trap circuit is
On the transmission line from the down converter to the terminal terminals,
A passage path for the upstream signal in the building in the transmission equipment provided on the transmission line;
Output path of the upstream signal in the ridge in the upconverter,
Input path of the upstream signal in the wing in the down converter,
The in-building CATV system according to claim 1, wherein the in-building CATV system is provided in at least one of the above. In the in-building CATV system according to claim 2,
The high-frequency signal for frequency conversion is set to a frequency higher than the upstream signal in the building, and the trap circuit is incorporated in the transmission device, the up-converter, or the down-converter In
An in-building CATV system, wherein the trap circuit is configured by connecting a resonant circuit to the in-building up signal transmission path through an inductive reactance. In the in-building CATV system according to claim 2,
When the high-frequency signal for frequency conversion is set to a frequency lower than the upstream signal in the ridge, and the trap circuit is incorporated in the transmission device, the up-converter, or the down-converter In
An in-building CATV system, wherein the trap circuit is configured by connecting a resonance circuit to the in-building up signal transmission path through a capacitive reactance. An in-band transmission loss of the in-building upstream signal caused by the in-building upstream signal passing through the trap circuit on the in-building upstream signal or the upstream signal transmission path from the up converter to the down converter. The in-building CATV system according to any one of claims 1 to 4, further comprising an equalizer for compensation. The equalizer is
On the transmission line from the down converter to the terminal terminals,
A passage path for the upstream signal in the building in the transmission equipment provided on the transmission line;
An input path of the upstream signal in the up-converter,
Output path of the upstream signal in the ridge in the upconverter,
Input path of the upstream signal in the wing in the down converter,
An output path of the upstream signal in the down converter;
The in-building CATV system according to claim 5, wherein the in-building CATV system is provided in at least one of the above. The in-building CATV system according to any one of claims 1 to 6, wherein the down-converter is provided between a lead-in line from an external bidirectional CATV system and a transmission line in a building,
A first downlink signal passing path for sending a downlink signal input from an external bidirectional CATV system via the lead-in line onto the transmission line;
First high-frequency signal generating means for generating a high-frequency signal having the same frequency as the high-frequency signal used by the terminal-side up-converter to frequency-convert the upstream signal output from the terminal device into the in-building upstream signal;
By taking in the building up signal transmitted from the up converter via the transmission line, and mixing the building up signal and the high frequency signal generated by the first high frequency signal generating means, First frequency converting means for frequency-converting an upstream signal to the upstream signal, and sending the upstream signal after the frequency conversion to the service line side;
The down converter further comprising the trap circuit on an input path of the in-building upstream signal to the first frequency conversion means. In the building CATV system according to claim 5 or 6, a down converter provided between a lead-in line from an external bidirectional CATV system and a transmission line in a building,
A first downlink signal passing path for sending a downlink signal input from an external bidirectional CATV system via the lead-in line onto the transmission line;
First high-frequency signal generating means for generating a high-frequency signal having the same frequency as the high-frequency signal used by the terminal-side up-converter to frequency-convert the upstream signal output from the terminal device into the in-building upstream signal;
By taking in the building up signal transmitted from the up converter via the transmission line, and mixing the building up signal and the high frequency signal generated by the first high frequency signal generating means, First frequency converting means for frequency-converting an upstream signal to the upstream signal, and sending the upstream signal after the frequency conversion to the service line side;
Furthermore, at least one of the input path of the in-building upstream signal to the first frequency conversion means and the output path of the upstream signal from the first frequency conversion means includes the equalizer. A down converter characterized by that. The in-building CATV system according to any one of claims 1 to 6, wherein the up-converter is provided between the terminal terminal and a subscriber-side terminal device,
A second downlink signal passing path for sending a downlink signal from an external bidirectional CATV system that has been transmitted to the terminal terminal via a down converter and a transmission line, to the terminal device side;
Second high-frequency signal generating means for generating a high-frequency signal having the same frequency as the high-frequency signal used by the down converter to frequency-convert the in-building upstream signal into the original upstream signal;
The upstream signal output from the terminal device is captured, and the upstream signal and the high-frequency signal generated by the second high-frequency signal generating means are mixed to frequency-convert the upstream signal into the in-building upstream signal, A second frequency converting means for outputting the upstream signal in the building after the frequency conversion to the terminal terminal side;
The up-converter further comprising the trap circuit on an output path of the in-building upstream signal from the second frequency conversion means. The in-building CATV system according to claim 5 or 6, wherein the up-converter is provided between the terminal terminal and a subscriber-side terminal device,
A second downlink signal passing path for sending a downlink signal from an external bidirectional CATV system that has been transmitted to the terminal terminal via a down converter and a transmission line, to the terminal device side;
Second high-frequency signal generating means for generating a high-frequency signal having the same frequency as the high-frequency signal used by the down converter to frequency-convert the in-building upstream signal into the original upstream signal;
The upstream signal output from the terminal device is captured, and the upstream signal and the high-frequency signal generated by the second high-frequency signal generating means are mixed to frequency-convert the upstream signal into the in-building upstream signal, A second frequency converting means for outputting the upstream signal in the building after the frequency conversion to the terminal terminal side;
Further, at least one of the input path of the upstream signal to the second frequency conversion means and the output path of the upstream signal from the second frequency conversion means includes the equalizer. An up-converter characterized by that. The in-building CATV system according to any one of claims 1 to 6, wherein the amplifying apparatus is provided on a transmission line from the down converter to each terminal on the subscriber side and amplifies a signal flowing through the transmission line,
A third downlink signal passing path for sending the downlink signal transmitted from the downconverter side to the terminal side;
An in-building upstream signal passing path for sending the in-building upstream signal transmitted from the up converter connected to the terminal terminal to the down converter side,
A signal amplifying means provided on at least one of the third downstream signal passage route and the in-building upstream signal passage route, and amplifies a downstream signal or an upstream signal flowing through the route;
And further comprising the trap circuit on the upstream signal passing path. The in-building CATV system according to claim 5 or 6, wherein the amplifying apparatus is provided on a transmission line extending from the down converter to each terminal on the subscriber side and amplifies a signal flowing through the transmission line,
A third downlink signal passing path for sending the downlink signal transmitted from the downconverter side to the terminal side;
An in-building upstream signal passing path for sending the in-building upstream signal transmitted from the up converter connected to the terminal terminal to the down converter side,
A signal amplifying means provided on at least one of the third downstream signal passage route and the in-building upstream signal passage route, and amplifies a downstream signal or an upstream signal flowing through the route;
And an equalizer on the upstream signal passing path in the building.

Images