Two-way CATV system using frequency division multiplexing

A two-way CATV system, in which a plurality of communication channels are set simultaneously in an upstream communication line between a plurality of end terminal equipment and a center equipment by using frequency division multiplexing, is disclosed. A digital transmultiplexer is arranged at each junction between a trunk line and a branch line for converting a frequency division multiplex signal into a time division multiplex signal. Frequency division multiplex signals from the terminal equipment are converted into time division multiplex signals, and then only a time slot corresponding to a frequency slot containing a signal therein is picked up to thereby prevent upstream noises from flowing into the trunk line.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a two-way CATV system for setting a 
plurality of communication channels in an upstream communication line to a 
central equipment (hereinafter referred to simply as a center) from a 
plurality of end terminal equipment (hereinafter referred to simply as 
terminals) by means of frequency division multiplexing. 
2. Description of the Related Art 
In conventional two-way CATV systems with communication channels arranged 
between terminals and a center unit, in order to reduce upstream noises in 
an upstream communication line, a plurality of switches called bridger 
gates 810 and 870 and so on adapted for turning on and off in response to 
instructions from the center unit are disposed in the vicinity of 
branching points or junctions 850, 840 and so on between a trunk line 830 
and branch lines 820, 821 and so on, so that only a bridger gate belonging 
to a branch line having a terminal transmitting a signal is closed in 
compliance with an instruction from the center unit, while bridger gates 
associated with the branch lines having no terminal transmitting a signal 
are kept open thereby to prevent noises from flowing into the trunk line 
from any branch line having no terminal which transmits a signal. In FIG. 
8, assume that only a terminal 861 is transmitting an upstream signal, 
while terminal 862 and other terminals are not transmitting any upstream 
signal. A center unit 800 controls the bridger gates 810, 870 and so on, 
and closes the bridger gate 810 alone, while keeping the other bridger 
gates including 870 open. Then, only a signal of the branch line 820 
associated with the terminal 861 is transmitted to the trunk line, while 
the signals of the other branch lines 821 and so on are prevented from 
entering the trunk line, thereby eliminating upstream noises. 
This conventional system for eliminating the upstream noises operates to 
eliminate such noises effectively in the case where there is only one 
concurrent communication channel in the upstream communication line and 
therefore only one bridger gate is open at the same time. Nevertheless, 
there are many cases in which an upstream communication line is used in 
frequency division multiplexing with a plurality of communication channels 
set at a time. 
In such a case, if communication channels are set at the same time between 
terminals associated with different branch lines and a center unit (for 
example, between a terminal 861 associated with a branch line 820 and a 
center unit 800, and between a terminal 862 associated with a branch line 
821 and the center unit 800 in FIG. 8, independently and at the same 
time), a plurality of bridger gates would be closed at the same time (in 
the cited example, the bridger gates 810 and 870 are closed at the same 
time), with a result that noises from a plurality of branch lines would 
flow into the trunk line, thereby making it impossible to eliminate noises 
completely. 
This problem is aggravated with an increase in the number of frequency 
multiplexing carrier waves and an increase in the number of communication 
channels set at the same time. 
SUMMARY OF THE INVENTION 
An object of the present invention is to eliminate upstream noises 
effectively when a multiplicity (several tens to several hundreds) of 
communication channels of a comparatively narrow bandwidth (several 
hundred kHz) are set in an upstream communication line by frequency 
division multiplexing with carriers arranged equidistantly for a two-way 
CATV system. 
In order to achieve the above-mentioned object, there is provided according 
to the present invention a two-way CATV system with a plurality of 
communication channels set by using frequency division multiplexing in an 
upstream communication line leading to a center from a plurality of 
terminals, wherein the communication line includes a trunk line connected 
to the center and a plurality of branch lines branching from the trunk 
line, and the CATV system further comprises filter means including a first 
digital transmultiplexer for converting a frequency division multiplex 
signal from the terminals into a time division multiplex signal, and means 
for sending out only a time slot corresponding to a frequency slot 
containing a signal to the trunk line after the conversion of a frequency 
division multiple signal from a terminal into a time division multiplex 
signal. In short, noises in the branch lines are prevented from flowing 
into the trunk line by taking out only a time slot containing a signal in 
each branch line. 
According to another aspect of the present invention, there is provided a 
two-way CATV system wherein the upstream signal on the trunk line is 
transmitted by using analog frequency division multiplexing, and the CATV 
system further comprises filter means including a first digital 
transmultiplexer for converting a frequency division multiplex signal from 
a terminal to a time division multiplex signal and a second digital 
transmultiplexer for converting a time division multiplex signal into a 
frequency division multiplex signal, and means for replacing a time slot 
containing no signal with zero after the conversion of a frequency 
division multiplex signal from a terminal into a time division multiplex 
signal by the first digital transmultiplexer, restoring the time division 
multiplex signal thus replaced into a frequency division multiplex signal 
again by the second digital transmultiplexer, and transmitting the 
frequency division multiplex signal thus restored to the trunk line. In 
short, a frequency division multiplex signal is transmitted to the trunk 
line from each branch line, thereby preventing noises from flowing into 
the trunk.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
In a two-way CATV system according to the present invention, a plurality of 
communication channels are set at the same time in an upstream 
communication line leading to a center from a plurality of terminals by 
using frequency division multiplexing. 
A general configuration of a first embodiment of the present invention is 
shown in the block diagram of FIG. 1. 
In FIG. 1, reference numeral 100 designates a center, numeral 130 a trunk 
network, numerals 120 and 121 branch lines connected to the trunk line 130 
at junctions 150 and 140, numerals 161 and 162 terminals connected to the 
branch lines 120 and 121, respectively, numerals 110 and 170 filter 
sections associated with the branch lines 120 and 121, respectively, and 
numeral 180 a two-way amplifier inserted in the trunk line. 
The center 100 includes center units 101, 102 and 103, and the filter 
section 110 includes a signal detector 112 and a filter 111. 
The communication line includes the trunk line 130 connected to the center 
100 and the branch lines 120, 121 and so on branching from the trunk line 
130. 
The number of branch lines 120, 121 and so on branching from the trunk line 
130 is, say, 10 to 20. The number of the terminals connected to respective 
branch lines 120, 121 and so on, on the other hand, is, say, 100 to 500. 
The junction 140, 150 and so on are junctions connecting the trunk line 130 
with the branch lines 120, 121 and so on. An upstream signal transmitted 
on each branch line 120, 121 and so on and the trunk line 130 is 
communicated by using analog frequency division multiplexing. 
A coaxial cable is used, for example, as a communication line having a 
transmission bandwidth of about 300 MHz. This transmission band is divided 
into an upstream communication band (0 to 50 MHz) and a downstream 
communication band (60 to 300 MHz). 
FIG. 2 is a diagram for explaining the operation of the filter sections 110 
and 170 shown in FIG. 1. 
FIG. 3 is a detailed block diagram showing the filter sections 110 and 170. 
In FIG. 3, numeral 300 designates a filter, and numeral 310 a signal 
detector corresponding to the devices 111 and 112 shown in FIG. 1, 
respectively. The filter 300 includes an A/D converter 301, an FDM-TDM 
converter 302, a time slot control unit 308, a TDM-FDM converter 304, and 
a D/A converter 305. 
FIG. 4 is a diagram for explaining the signal processing step in FIG. 3. 
The FDM-TDM converter 302 and the TDM-FDM converter 304 are realized by a 
digital transmultiplexer using the digital signal processing. 
First, an outline of the present embodiment will be explained with 
reference to FIGS. 1 and 2. 
This embodiment uses, in an upstream communication line, frequency division 
multiplexing using four carrier frequencies including f0, f1, f2 and f3 
arranged equidistantly (for example, a case of communicating with 
terminals using f0 (=35.0 MHz) for the center unit 1, f1 (=35.025 MHz) for 
the center unit 2, f2 (=35.05 MHz) for the center unit 3, and so on). 
The signal detector 112 monitors the branch line 120 to watch in which 
frequency band of f0, f1, f2 or f3 a signal exists by checking whether or 
not a signal level exceeds a predetermined value (decision level 204, 214, 
and so on). The filter 111 comprises a digital transmultiplexer, as 
explained later, and is capable of controlling the signals in the 
frequency bands of f0, f1, f2 and f3 as to whether they should be allowed 
to pass or blocked from passing to the trunk line individually. 
The filter 111 which is controlled by the signal detector 112 allows only a 
frequency band containing an upstream signal of the branch line 120 to 
pass to the trunk line. In the case where only a signal 201 of frequency 
f1 exists on the branch line 120, for instance, the filter 110 is 
controlled in the manner shown in FIG. 2(2-1), while if signals 210 and 
213 of the respective frequencies f0 and f3 are present on the branch line 
121, the filter 170 is controlled in the manner shown in FIG. 2(2-2). 
In this way, only a frequency band containing a signal therein is connected 
to the trunk line, and therefore noises 200, 202 and 203, which may be 
present in the branch line 120, and noises 211 and 212 in the branch line 
121 are prevented from flowing into the trunk line, thereby preventing the 
occurrence of what is called upstream noises, in which noises are produced 
on a plurality of branch lines and are intermixed on the trunk line. 
Now, the signal processing system for the filter will be explained with 
reference to FIGS. 3 and 4. 
A frequency multiplexed signal applied to the filter 300 from each branch 
line is converted into a digital signal by the A/D converter 301, and 
further converted into a time division multiplex signal by the FDM-TDM 
converter 302. The time slot control section 303 replaces the value of a 
time slot containing no signal with "0" in accordance with an instruction 
from the signal detector 310. The time division multiplex signal in a time 
slot, which contains no signal and whose time slot value has been replaced 
by zero, is again converted into a frequency division multiplex signal by 
the TDM-FDM converter 304, and the signal thus converted is further 
converted into an analog signal by the D/A converter 305 and sent out onto 
the trunk line. 
Assume that an input signal exists only in the frequency f1 as shown in 
FIG. 4(4-1) with noises present in the frequencies f0, f2 and f3. The 
signal, which has passed the A/D converter 301 and the FDM-TDM converter 
302, becomes a time division multiplex signal with the frequencies f0, fl, 
f2 and f3 corresponding to the time slots t0, t1, t2 and t3, respectively, 
as shown in FIG. 4(4-2). The signal detector 310 detects that a signal of 
the frequency fl alone is present in a branch line, and hence issues an 
instruction to the time slot control section 303 to make the time slots 
other than t1 zero. The time slot control section 303 makes t0, t2 and t3 
zero in accordance with the instruction from the signal detector 310. An 
output of the time slot control section 303 is converted again into a 
frequency division multiplex signal by the converter 304 as shown at (4-3) 
in FIG. 4, and further into an analog signal by the D/A converter 305. 
Since the time slots associated with noises have been made zero by the 
time slot control section 303, noises are eliminated from the output of 
the D/A converter 305 to make only a signal exist there. 
In this way, passage or nonpassage of individual signals of respective 
frequency bands to the trunk line is controlled in the filter 300 by 
combining FDM-TDM conversion with TDM-FDM conversion and replacing a time 
slot containing no signal by zero after the conversion into a time 
division multiplex signal. 
Although the aforementioned embodiment has been explained as having four 
frequency slots, the present invention is not limited in the number of 
frequency slots. Further, instead of detecting a signal level in order to 
select a time slot, instructions from the center units may be used for 
simplification in view of the fact that respective specific frequencies of 
individual terminals are under the control of the center units in many 
cases. 
FIG. 5 is a block diagram showing a general configuration of a second 
embodiment of the present invention. 
In FIG. 5, numeral 500 designates a center, numeral 550 a trunk network, 
numerals 510 and 540 filter sections, numerals 520 and 521 branch lines 
connected to the trunk line 550 at the filter sections 510 and 540, 
respectively, and numerals 530 and 531 terminals connected to the branch 
lines 520 and 521, respectively. The center 500 includes center units 501, 
502 and 503 and digital transmultiplexer (TDM-FDM converter) 505. The 
filter section 510 includes a signal detector 512, a FIFO 
(first-in-first-out memory) 513, a digital transmultiplexer (FDM-TDM 
converter 514 and a multiplexer 511. 
FIG. 6 is a diagram for explaining the steps of signal processing in the 
filter sections 510 and 540 and the TDM-FDM converter 505 in the center, 
shown in FIG. 5. 
FIG. 7 is a schematic diagram of the signal processing in the FDM-TDM 
converter 514 and the TDM-FDM converter 505. 
First, the operation of each device will be explained. The FDM-TDM 
converter 514, after having performed A/D conversion of an upstream 
frequency division multiplex signal transmitted along the branch line 520, 
converts it into a time division multiplex signal by the digital signal 
processing. If the terminal 530 of the branch line 520 transmits an 
upstream signal of the frequency f1 but the branch line 520 has no 
terminal, which transmits a signal, other than the terminal 530, for 
example, the FDM-TDM converter 514 is supplied with an input signal (an 
upstream signal on the branch line 520) as shown in FIG. 7(7-1). This 
signal is converted by the FDM-TDM converter 514 so that the frequency 
bands f0, fl, f2 and f3 correspond to the time slots t0, t1, t2 and t3, 
respectively, as shown in FIG. 7(7-2). The TDM-FDM converter 505, which 
operates in the exactly opposite way, converts a time division multiplex 
signal transmitted on the trunk line 550 into a frequency division 
multiplex signal by the digital signal processing, and then converts the 
frequency division multiplex signal into an analog frequency division 
multiplex signal through a D/A converter. In this way, as shown in FIG. 
7(7-3), the signal is converted so that the time slots t0, t1, t2 and t3 
correspond to the frequency bands f0, fl, f2 and f3, respectively. 
The FIFO (first-in-first-out memory) 513 is provided to absorb a difference 
in timing between the time division signal on the trunk line and the time 
division signal produced from the FDM-TDM converter. 
The signal detector 512 checks the signal level of each time slot converted 
into a time division multiplex signal, detects a frequency band of the 
branch line 520, in which an upstream signal is present, on the basis of 
the correspondence between the time slot and the frequency slot, and, on 
the basis of this result, controls the multiplexer 511 to effect 
multiplexing of only a time slot containing a signal in the time division 
signal on the trunk line. 
Now, an explanation will be made of the overall signal processing 
principally with reference to FIG. 6. 
In FIG. 5, assume that the terminals 530 and 531 of the branch lines 520 
and 521 are transmitting the frequencies f1 and f2, as shown in FIGS. 
6(6-1) and 6(6-2), respectively. Take the branch line 520 as an example. 
An input frequency multiplex signal (6-1) to the FDM-TDM converter 514 is 
converted into a time division multiplex signal in the FDM-TDM converter 
514 so that F0, F1, F2 and F3 correspond to T0, T1, T2 and T3, as shown in 
FIG. 6(6-3) for example. The signal detector 512 checks the signal levels 
of T0, T1, T2 and T3, decides that only F1 contains a signal, and controls 
the multiplexer 511 so that the time slot T1 alone may be multiplexed in 
the time division signal on the trunk line. Also, this is exactly 
applicable to the branch line 521, in which case only the time slot T2 
corresponding to F2 in the signals shown in FIG. 6(6-2) transmitted from 
the terminal 531 is multiplexed in the time division signal of the trunk 
line. 
As a result, only those time slots, in which the time division multiplex 
signals on the trunk line correspond to the signals existing on the 
respective branch lines as shown in FIG. 6(6-5), are multiplexed, whereas 
the time slots T0, T2 and T3 shown in FIG. 6(6-3) and the time slots T0, 
T1 and T3 shown in FIG. 6(6-4) corresponding respectively to 600, 602 and 
603 shown in FIG. 6(6-1) and 610, 611 and 613 shown in FIG. 6(6-2) are not 
multiplexed on the trunk line, so that noises are prevented from flowing 
into the trunk line. 
In this way, an upstream signal transmitted along the trunk line 550 as a 
time division multiplex signal is restored to an FDM signal by the TDM-FDM 
converter 505 provided at the center 500, and therefore a communication 
line containing only minimum upstream noise can be obtained without 
modifying the center units 501, 502 and 503 and the terminals 530, 531 and 
so on. 
Also, it is possible to take out respective time slots directly in the form 
of time division signals, as they are, without using the TDM-FDM converter 
505 and to supply the time division signals to respective center units, 
thereby making them perform required processing. 
Further, although the present invention has been described as to the 
communication between a central equipment and end terminal equipment, the 
present invention is not necessarily limited to its application to such 
communication between a central equipment and end terminal equipment. 
Instead, the present invention may be applicable to a case where the 
central equipment is provided with a frequency converter, whereby an 
upstream signal transmitted from a terminal by way of an upstream 
communication line is converted to have a frequency alloted to a 
downstream communication line, and then the resultant signal is 
transmitted through the downstream communication line, thereby realizing 
the communication between different end terminal equipment, and thus 
making it possible to effectively eliminate upstream noises in the 
upstream communication line.