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BACKGROUND OF THE INVENTION
This invention relates generally to CATV systems and is more specifically
directed to the upstream transmission of data in a two-way CATV system.
Cable television systems typically include a central master source of
television programming information, or headend, which imparts programs at
different assigned frequencies to a network of cable connections. The
network, or cable plant, includes a main distribution cable to which is
coupled a plurality of "drop" cables, each of which is coupled to an
individual subscriber terminal. Particularly in large metropolitan areas,
CATV systems may include one or more master sources which are patched into
a common distribution system. CATV signals are broadcast from the headend
to individual subscribers in a "downstream" direction over different
assigned carrier frequencies typically from 50 to 450 MHz. These
downstream signals are in conventional television video signal format and
include synchronization, audio, video, etc., components. These downstream
signals are transmitted in a branched-out arrangement where all headend
initiated signals are provided to all remote subscribers, if authorized.
In a two-way CATV system each subscriber is able to transmit signals back
to the CATV headend. These subscriber-initiated signals may include
program purchasing requests, opinion poll responses and CATV converter
status information. These upstream signals typically make use of out of
band frequencies such as in the 5-32.5 MHz band. The upstream signal
distribution network is in the form of a "merging tree topology" in which
the signals generated by many sources, or subscribers, converge and are
transmitted on a single transmission line back to the CATV headend.
In an effort to increase the number of CATV channels available, several
types of coherent headends have been devised. One coherent headend is
termed Harmonically Related Coherent (HRC), while another is termed
Interval Related Coherent (IRC). The HRC headend requires all cable
channel picture carriers to be shifted to harmonics of a 6 MHz reference
signal. IRC headend channels operate in normally assigned frequencies,
except channels 5 and 6, which must be shifted 2 MHz to fall in line with
the other channels. In yet another arrangement all cable channel picture
carriers are spaced 6 MHz apart from an adjacent channel with the
exception of channels 5 and 6. Channels 4 and 5 are separated by less than
6 MHz, while channels 6 and 7 are spaced greater than 6 MHz apart. In all
of the aforementioned CATV signal distribution arrangements, essentially
all CATV downstream signals are harmonically related.
In general, the main distribution cable is well maintained in a CATV
system. However, the connectors coupling either the drop cable to the
distribution cable or coupling a subscriber terminal to a drop cable are
frequently subject to wear and corrosion. A defective connector produces
nonlinearities in the signal handling characteristics of the cable. Under
such conditions, a faulty connector operates as a mixing diode in
generating sum and difference products of all CATV downstream signals.
Only those subscribers having a faulty connector will experience the
aforementioned video signal distortion due to the thus generated cross-
and intermodulation products. However, these unwanted harmonics are
coupled upstream to the CATV headend and in a two-way CATV system
seriously degrade upstream communication. Because of the various
components of the video signal and side bands associated therewith, the
number of modulation products thus produced is very large and
substantially contributes to the noise figure across the entire video
band. In addition, because television signals employ only downward
modulation from a clamped synchronization signal, the effective carrier
level of each channel varies according to the video content of the signal.
Thus, the various modulation products are a function of video signal
content as well as carrier and subcarrier signal frequencies and, as such,
present a continually varying source of noise which is extremely difficult
to eliminate, or even minimize.
An example of a two-way CATV system utilizing selected frequencies for
upstream and downstream communication is disclosed in U.S. Pat. No.
3,943,447 to Shomo. The system described therein takes advantage of a
transparent window, in both the upstream and downstream directions, to
communications signals over a frequency band from 10-300 KHz wherein the
communications signals follow the path of a 60 Hz power signal throughout
the system. It is claimed that these communications signals do not
interfere with the high frequency television signals being transmitted,
nor are they subject to interference by such television signals. This
system permits bi-directional communication between any two or more points
linked by such a CATV system. The low frequencies of the signals utilized
in this system limit its data handling capacity and thus the amount of
information which can be transmitted.
The present invention is intended to overcome the limitations of the prior
art and solve the aforementioned problems by providing a system which
makes use of nonharmonic frequencies for upstream signal transmission in a
two-way CATV system.
OBJECTS OF THE INVENTION
Accordingly, it is an object of the present invention to provide improved
upstream data transmission in a two-way CATV system.
It is another object of the present invention to reduce the effects of
common mode distortion arising from the mixing of harmonically related
downstream carrier signals in a two-way CATV system.
Still another object of the present invention is to reduce the effects of
nonlinear downstream cable transmission characteristics on upstream data
transmission in a two-way CATV system.
A further object of the present invention is to utilize a single signal
source for generating upstream carrier signals at several predetermined
frequencies in a two-way CATV system.
It is yet another object of the present invention to improve upstream
communication in a two-way CATV system by alternating between two carrier
signal frequencies in order to minimize the effects of signal interference
.
BRIEF DESCRIPTION OF THE DRAWINGS
The appended claims set forth those novel features believed characteristic
of the invention. However, the invention itself, as well as further
objects and advantages thereof, will best be understood by reference to
the following detailed description of a preferred embodiment taken in
conjunction with the accompanying drawings, in which:
FIG. 1 is a simplified block diagram of a two-way CATV system embodying the
principles of the present invention; and
FIG. 2 illustrates various modulation products resulting from video and
audio carrier and sub-carrier downstream frequencies in a CATV system as
well as the frequencies of signals used for upstream transmissions in the
CATV system in accordance with the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIG. 1, there is shown in simplified block diagram form a
two-way cable television (CATV) system 10 for transmitting upstream
signals at uniquely determined frequencies in accordance with the present
invention.
The CATV system 10 includes a head end portion 12 from which control and
programming signals are provided to a plurality of CATV subscriber
terminals 14, 16 and 18. Although FIG. 1 shows only three subscriber
terminals included in the CATV system 10, it is to be understood that the
present invention contemplates the distribution of the cable television
signals to a large number of subscriber terminals, each having associated
therewith a respective cable television service controller and television
receiver which is not shown in FIG. 1 as it does not form a part of the
present invention.
The CATV system 10 includes a distribution cable 20 and a plurality of drop
cables 22, 24 and 26. Typically, each subscriber terminal is coupled to
the distribution cable 20 via a respective drop cable. The CATV headend 12
includes a 5.5 MHz receiver 38 and a 11.0 MHz receiver 40 coupled to the
distribution cable 20 via a diplex filter 36. Therefore, a 5.5 MHz
upstream signal is provided to receiver 38 via diplex filter 36, while an
11.0 MHz upstream signal is provided to receiver 40 via diplex filter 36.
The 5.5 and 11.0 MHz receivers 38, 40 are each coupled to a microcomputer
34 in headend 12. Microcomputer 34 is responsive to the upstream signals
provided to respective receivers 38, 40 and performs various functions in
response thereto. For example, microcomputer 34 may implement a subscriber
authorization operation following a subscriber-initiated request for CATV
programming. On the other hand, the primary function of the CATV headend
12 with respect to the upstream data may be merely to store this
information for later use such as in the case of subscriber polling
responses or CATV converter status information, e.g., power, program
viewed, etc. Microcomputer 34 is further coupled to a transmitter 42
which, in turn, is coupled by means of diplex filter 36 to the
distribution cable 20. Therefore, microcomputer-generated control data for
controlling each of the subscriber terminals 14, 16 and 18 may be provided
to the distribution cable 20 via diplex filter 36 and transmitter 42. The
downstream data provided by transmitter 42 to each of the subscriber
terminals may further include subscriber address and program authorization
data as well as CATV video program signals. CATV headend 12 may include
additional components such as an encoder/decoder, disc drives and a tape
backup. These elements of the CATV headend 12 are not shown in FIG. 1 as
they do not form a part of the present invention.
For simplicity, only the details of CATV subscriber terminal 14 are
discussed herein since the remaining subscriber terminals 16 and 18 are
similarly configured for performing similar functions. Only the signal
generation portion of CATV subscriber terminal 14 is discussed in detail
herein, since the manner in which a subscriber terminal receives and
responds to CATV headend-initiated downstream data is not a part of the
present invention. Subscriber terminal 14 includes a subscriber input
device 48, such as a keyboard, by means of which a viewer may enter data.
This data may typically be in the form of a program request or
headend-requested subscriber polling information. Subscriber input device
48 is coupled to a microcomputer 46 which may either generate data in
response to inputs from the subscriber input device 48, or may generate
upstream data in response to downstream headend-initiated requests. Two
outputs are generated by microcomputer 46: one is a data output provided
to modulator 44, the other is a control output provided to switch 50. The
data output represents information to be communicated to CATV headend 12,
while the control output controls the operation of switch 50. Switch 50
may take on any of a larger number of switching device configurations and
may generally be termed an electronic switch. Two additional inputs are
provided to switch 50. One input is from an 11 MHz oscillator 52, while
the other input is from a divide-by-two circuit 54 which, in turn, is also
coupled to the 11 MHz oscillator. The output of the divide-by-two circuit
54 to switch 50 is a 5.5 MHz signal. Switch 50, in response to the control
input from microcomputer 46, provides either an 11 MHz or a 5.5 MHz signal
to modulator 44. In one embodiment of the present invention, the 5.5 and
11 MHz signals are alternately provided by switch 50 to modulator 44.
Modulator 44 is also coupled to microcomputer 46 and is controlled by the
data output therefrom. Therefore, the 5.5 and 11 MHz output signals from
switch 50 are alternately modulated by modulator 44 in accordance with
data from microcomputer 46 for transmission via drop cable 22 to CATV
headend 12. By alternately transmitting upstream at two different
frequencies, upstream data transmission reliability is increased while the
effects of interference on upstream signal transmissions are reduced. Each
CATV subscriber terminal will continue to transmit upstream until its
upstream data signal is successfully communicated to CATV headend 12 and
an acknowledge signal is received from the transmitter 42 of CATV headend
12. One example of the manner in which such a CATV subscriber terminal
control signal is generated and provided thereto is described in copending
patent application "Two-Way CATV System With AML Commands", filed in the
name of Richard W. Citta, and assigned to the assignee of the present
application.
Downstream signals from the cable headend 12 to individual subscribers
typically include subscriber address and program authorization information
which are transmitted on frequencies between 50 and 450 MHz in a preferred
embodiment. Upstream data from each subscriber terminal to the CATV head
end 12 is preferably transmitted within a frequency band of 5-32.5 MHz.
Data transmitted upstream to the CATV headend 12 may include such
information as subscriber responses to headend initiated polling signals,
subscriber terminal power status information, and subscriber-initiated
program requests. The 17.5 MHz between the upstream and downstream signal
frequencies represents a guard band for providing frequency isolation
between these two groups of CATV signals.
However, complete isolation between the upstream and downstream channels is
not available in a typical CATV system. For example, the drop cable
connectors 28, 30 and 32 may become damaged, corroded, or subject to a
physical strain so as to impair the electrical connection resulting in
degraded connector performance. Typically, under any of the aforementioned
situations, the drop connector will function electrically as a mixing
diode in adding and subtracting all of the downstream CATV video carriers
and sidebands associated therewith. With in excess of 50 channels
available in some CATV systems and each channel having associated
therewith several carrier frequencies, a large number of cross- and
intermodulation products will be formed by a malfunctioning or defective
drop connector. These unwanted products appear as noise in the downstream
video signals and degrade the video signal provided to the subscriber
terminal coupled to the drop cable via the malfunctioning or damaged drop
connector. Thus, a defective drop connector affects only the quality of
the downstream video signal provided to its associated subscriber
terminal. However, the effect of a defective drop connector is
substantially different with respect to upstream transmitted signals.
The inter- and crossmodulation products generated by the defective drop
connector are not only transmitted downstream, but are also coupled
upstream to the CATV headend 12. Thus, a single defective drop connector
in the two-way CATV system 10 will degrade the upstream data channel for
all subscriber terminals by providing various CATV signal modulation
products to the CATV headend 12.
Referring to FIG. 2, there is shown the frequencies of various interfering
modulation products generated by a defective drop connector which are
reflected upstream to the CATV headend 12. Because the downstream video
carrier signals are 6 MHz apart over the band of 50-450 MHz, the
interfering signal spectrum shown in FIG. 2 is repeated each 6 MHz
increment over the upstream frequency band. Because this interference
spectrum repeats itself every 6 MHz, only the presence of interfering
signals in the band from approximately 6-12 MHz will be considered herein,
with the understanding that a similar interference spectrum and the
following discussion applies over the entire upstream frequency band of
5-32.5 MHz.
As shown in FIG. 2, strong modulation products resulting from downstream
video carrier signals are present at 6 and 12 MHz. Each downstream CATV
channel has an audio carrier associated therewith displaced 4.5 MHz above
its video carrier. The modulation product at 10.5 MHz, as well as the
modulation product at 4.5 MHz, thus results from intermodulation of such
downstream audio and video carriers. Finally, a modulation product is
shown at 7.5 MHz which represents cross-modulation of audio and adjacent
channel video downstream carrier signals. The frequency distribution of
the various signals shown in FIG. 2 falls off exponentially due to the
various sideband frequencies displaced .+-.15 KHz, .+-.30 KHz, etc., from
the respective downstream carrier frequencies. The modulation products
discussed thus far represent the primary upstream interfering signals in a
two-way CATV system. In addition, various secondary interfering signals
are seen by the CATV headend. These secondary interfering signals arise
primarily from cross and intermodulation of the chroma, or color,
components of the downstream video carrier signals and are shown in FIG. 2
at frequencies of 9.58 MHz, or 3.58 MHz above the 6 MHz modulation
product, and 8.42 MHz, or 3.58 MHz below the 12.0 MHz modulation product.
Additional secondary sources of interference occur at 6.58 MHz resulting
from modulation products of downstream audio and chroma carriers.
Similarly, a secondary source of interference occurs at 11.4 MHz also
resulting from modulation products of downstream audio and chroma
carriers. Thus, it can be seen from FIG. 2 that various sources of
interference occur between the video carriers induced modulation products
in a two-way CATV system having a downstream signal transmission
discontinuity.
The present invention improves upstream data communication in a two-way
CATV system by minimizing the effects of the aforementioned primary and
secondary sources of interference. This is accomplished by determining the
optimum frequencies for upstream signal transmission in view of the
various aforementioned sources of interference encountered in a two-way
CATV system. Application of the present invention can be seen from FIG. 2
wherein are shown in dotted line form the upstream signal frequencies
utilized in a preferred embodiment. From FIG. 2, it can be seen that at
5.5 and 11.0 MHz the absence of either primary or secondary interfering
signals permits the upstream signals to be transmitted free of unwanted
interference. In addition, by utilizing two harmonically related
frequencies, a single frequency source such as a conventional oscillator
circuit 52 in combination with a frequency divider 54 which may be
selectively engaged for generating both upstream signal frequencies.
Finally, switch 50 under the control of microcomputer 46 permits alternate
upstream signal transmission at 5.5 and 11.0 MHz in order to provide a
second backup channel for more reliable upstream data communication. Thus,
the use of the present invention in a two-way CATV system not only
substantially improves upstream communication performance but also
simplifies and reduces the cost of each individual subscriber terminal.
There has thus been shown an improved arrangement for upstream signal
transmission in a two-way CATV system. Upstream carrier frequencies are
utilized for the transmission of upstream signals for minimizing the
effects of cross- and intermodulation products of the downstream video and
audio carrier signals which are coupled upstream by discontinuities in the
cable of the two-way CATV system. While particular embodiments of the
present invention have been shown and described, it will be obvious to
those skilled in the art that changes and modifications may be made
without departing from the invention in its broader aspects. Therefore,
the aim in the appended claims is to cover all such changes and
modifications as fall within the true spirit and scope of the invention.
The matter set forth in the foregoing description and accompanying
drawings is offered by way of illustration only and not as a limitation.
The actual scope of the invention is intended to be defined in the
following claims when viewed in their proper perspective based on the
prior art.
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