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| United States Patent |
5,841,563
|
|
Effenberger
|
November 24, 1998
|
Method and system for efficient optical transmission of NTSC video
Abstract
A technique for delivering analog video over fiber-to-the-home (FTTH)
networks addresses a fundamental problem of the standard signal format,
i.e., power budget constraint, by increasing the usable optical signal
efficiency. In particular, a technique is provided for transmitting an
efficient modified analog video which is compatible with existing
receivers. More specifically, the synchronization portion of a standard
NTSC video signal is reduced in amplitude during transmission, producing
an appreciable increase in the allowable optical modulation index (OMI).
| Inventors:
|
Effenberger; Frank J. (New Providence, NJ)
|
| Assignee:
|
Bell Communications Research, Inc. (Morristown, NJ)
|
| Appl. No.:
|
738648 |
| Filed:
|
October 29, 1996 |
| Current U.S. Class: |
348/533; 348/528; 348/534; 348/682; 348/683; 398/154 |
| Intern'l Class: |
H04B 010/04; H04J 014/08 |
| Field of Search: |
348/528,533,682,683,534,607,678,608,680
359/158,161,173,180,188,189,195,125,137
|
References Cited [Referenced By]
U.S. Patent Documents
| 3699256 | Oct., 1992 | Roth | 328/135.
|
| 4010322 | Mar., 1977 | Nathanson | 340/311.
|
| 4216497 | Aug., 1980 | Ishman et al. | 358/84.
|
| 5161187 | Nov., 1992 | Kajita et al. | 380/15.
|
| 5210606 | May., 1993 | Lagoni et al. | 358/148.
|
| 5379075 | Jan., 1995 | Nagasawa et al. | 348/678.
|
| 5387941 | Feb., 1995 | Montgomery et al. | 348/473.
|
| 5598274 | Jan., 1997 | Ogura et al. | 358/335.
|
| 5717469 | Feb., 1998 | Jennes et al. | 348/571.
|
Other References
"The Clipping Penalty in Fiber-Based, Combined AM-VSB . . . ", G. R. Joyce
et al., IEEE Phot. Tech. Lett., vol. 6, No. 11, pp. 1368-1370, Nov. 1994.
"Optimization of Fiber/Coax Upgrades for FITL Systems . . . ", T. E.
Chaprun et al., NFOEC '94, pp. 329-340 (1994).
"Transmission and distribution of a multichannel AM-VSB TV signal . . . ",
C. J. Richard et al., Ann. Telecommun., 49, No. 9-10, pp. 527-542, 1994.
|
Primary Examiner: Pascal; Leslie
Attorney, Agent or Firm: Giordano; Joseph, Hey; David A., Yeadon; Loria B.
Claims
What is claimed is:
1. A method for reducing distortion in an NTSC video signal comprising the
steps of:
a) providing a plurality of video signals from respective sources;
b) synchronizing the video signals and generating a sync. signal associated
therewith;
c) modulating the video signals and the sync. signal with a transmitting RF
amplifier, the gain of the transmitting amplifier being reduced a
predetermined amount during a sync. period during which the sync. signal
is transmitted, the predetermined amount being measured relative to the
gain of the transmitting amplifier during periods during which the video
signals are transmitted; and
d) receiving the modulated video signals and the sync. signal with a
receiver that is tuned and detected by automatic gain control circuitry,
the automatic gain circuitry detecting a relative decline in power during
the sync. period and forcing a gain increase corresponding to the
predetermined amount.
2. The method according to claim 1 wherein the predetermined amount is
about 50%.
3. The method according to claim 1 wherein the sync. signal and the
modulated video signals are transmitted via optical fiber.
4. A broadcasting system having reduced distortion in an NTSC video signal
comprising:
a) means for providing a plurality of video signals from respective
sources;
b) means for synchronizing the video signals and generating a sync. signal
associated therewith;
c) means for modulating the video signals and the sync. signal with a
transmitting RF amplifier, the gain of the transmitting amplifier being
reduced a predetermined amount during a sync. period during which the
sync. signal is transmitted, the predetermined amount being measured
relative to the gain of the transmitting amplifier during periods during
which the video signals are transmitted; and
d) means for receiving the modulated video signals and the sync. signal
with a receiver that is tuned and detected by automatic gain control
circuitry, the automatic gain circuitry detecting a relative decline in
power during the sync. period and forcing a gain increase corresponding to
the predetermined amount.
5. The system according to claim 4 wherein said predetermined amount is
about 50%.
6. The system according to claim 4 wherein the sync. signal and the
modulated video signals are transmitted via optical fiber.
7. A method of transmitting modified NTSC video signals in a format
characterized by reduced distortion comprising the steps of:
a) generating a plurality of video signals;
b) synchronizing the plurality of video signals utilizing a synchronizing
signal; and
c) transmitting the plurality of video signals and the synchronizing signal
over optical fiber with an adjustable gain amplifier, the gain of the
adjustable gain amplifier being reduced during intervals during which the
synchronizing signal is transmitted.
8. The method according to claim 7 wherein the gain of the adjustable gain
amplifier is reduced by about 50%.
9. The method according to claim 7 further comprising the step of receiving
transmitted video signals and the synchronizing signal, the received
signals being amplified with an adjustable gain amplifier configured to
increase its gain during the periods corresponding to the synchronizing
signal by an amount corresponding to an amount by which the transmitted
synchronizing signal is decreased.
10. A system of transmitting modified NTSC video signals in a format
characterized by reduced distortion comprising:
a) means for generating a plurality of video signals;
b) means for synchronizing the plurality of video signals utilizing a
synchronizing signal; and
c) means for transmitting the plurality of video signals and the
synchronizing signal over optical fiber with an adjustable gain amplifier,
the gain of the adjustable gain amplifier being reduced during intervals
during which the synchronizing signal is transmitted.
11. The system according to claim 10 wherein the gain of the adjustable
gain amplifier is reduced by about 50%.
12. The system according to claim 10 further comprising means for receiving
transmitted video signals and the synchronizing signal, the received
signals being amplified with an adjustable gain amplifier configured to
increase its gain during the periods corresponding to the synchronizing
signal by an amount corresponding to an amount by which the transmitted
synchronizing signal is decreased.
13. A video transmitter comprising:
a) video synchronizer circuit which synchronizes respective outputs from a
plurality of video sources to produce a video signal and a sync. signal;
b) pilot generator which produces a pilot tone; and
c) an adjustable gain RF receiver for producing a modulated, modified
analog video signal on the basis of the video signal, the sync. signal,
and the pilot tone, the gain of the RF receiver being reduced by a
predetermined amount during periods during which the sync. signal is
detected.
14. The video transmitter according to claim 13, wherein the modulated,
modified analog video signal is converted to an optical signal which is
transmitted along an optical fiber network.
15. The video transmitter according to claim 13 wherein the predetermined
amount is 50%.
16. A video receiver comprising:
a) a pilot receiver circuit which detects a pilot signal from a received,
modulated analog video signal and produces a gain control signal in
response thereto, the received, modulated analog video signal being
attenuated by a predetermined amount during periods corresponding to a
sync. signal; and
b) an adjustable gain amplifier which demodulates the received analogy
video signal to produce a baseband video signal, the gain of the amplifier
being adjusted on the basis of the gain control signal whereby the gain of
the received, modulated analog signal is increased by the predetermined
amount to recover the sync. signal.
17. The video receiver according to claim 16 wherein the received analog
video signal is converted to an electrical signal from an optical signal
prior to being provided to the pilot receiver circuit and the adjustable
gain amplifier.
18. The video receiver according to claim 16 wherein the predetermined
amount is 50%.
Description
RELATED APPLICATION
This application claims the benefit of U.S. Provisional application Ser.
No. 60/024,280, filed 21 Aug. 1996, entitled "Efficient Optical
Transmission Of NTSC Video".
BACKGROUND OF THE INVENTION
This invention relates to the field of optical signal transmission. More
particularly, it relates to a method and system for transmitting NTSC
video signals in a modified format to reduce distortion without additional
equipment and in a manner compatible with existing systems.
There is a substantial market for transmitting high-quality amplitude
modulation, vestigial sideband (AM-VSB) video in national television
standard committee (NTSC) format over optical fiber. Currently, this
technique is used entirely in the feeder portion of existing networks,
where the high equipment costs can be shared over many customers. Now, as
networks evolve towards higher interactivity, the fiber is moving deeper
into the access network. The ultimate goal of this evolution is
fiber-to-the-home (FTTH). The salient questions are whether analog video
over FTTH technically feasible, and how much will it cost. These questions
have been previously addressed, e.g., by G. R. Joyce, R. Olshansky, and R.
Gross, "The Clipping Penalty in Fiber-Based, Combined AM-VSB and
Compressed-Digital-Video Transmission Systems", IEEE Phot. Tech. Lett.
Vol. 6, No. 11, pp. 1368-70, (1994); and by T. Chapuran and K. Lu,
"Optimization of Fiber/Coax Upgrades for FITL Systems with Analog &
Digital Video Transmission", NFOEC'94, pp. 329-40 (1994). These works
indicate that while analog video over fiber is definitely feasible in
these applications, it demands high power and linearity from the optical
transmitter and receiver, as suggested by C. J. Richard et al.,
"Transmission and distribution of a multichannel AM-VSB TV signal on a
single mode optical fiber for CATV videocommunication networks", Ann.
Telecommun. 49, pp. 527-542, 1994. Such technical constraints translate
into costs that are too high in a FTTH setting.
To illustrate this, consider the analog video fiber transmission systems
available today. The technical constraints are well understood, and all
the straightforward methods of performance enhancement have already been
used. In other words, optical analog is a mature technology. The current
costs for the transmitters are high, and these cannot be shared by many
optical receivers. For example, a typical 550 MHz transmitter costs about
$7,500 and has just enough power to serve 8 receivers at a range of about
6.1 km. The receivers are nontrivial pieces of equipment, requiring both
low noise and distortion. The typical receiver costs about $1,000. Using
these costs, optical analog would cost about $2000 per terminal node, even
if the fiber were free. To be cost effective, the optical node must be
shared by many subscribers; however, in FTTH systems there is a node at
each subscriber. Thus, the key is to make optical analog less expensive.
The source of the problem is the fragile nature of the AM-VSB signal. This
format is actually very efficient in bandwidth, because it delivers the
uncompressed information content of NTSC video (100 Mb/s) in a bandwidth
of 6 MHz. This high bandwidth efficiency implies a signal that is very
susceptible to noise and transmission impairments. This is attested to by
the fact that a carrier to noise ratio (CNR) of over 43 dB is required for
the signal to be of acceptable quality. The specification for composite
second order (CSO) distortion dictates that the total power of all carrier
intermodulation products falling in a channel be 55 dB below the carrier
power in that channel. Even more, the specification for composite triple
order (CTO) interference requires that the third order intermodulation
power in a channel be 60 dB below the carrier power for that channel (it
is noted that the term CTO is used here to refer to all the distortion
products that originate from the third order nonlinearity of the system;
the commonly used composite triple beat (CTB) refers only to a subset of
the possible products). These very stringent requirements place a heavy
burden on the transmission equipment.
In order to understand these requirements for an optical transmission
system, consider first the problem of CNR. This quantity is given by the
following equation for a single channel,
##EQU1##
where P.sub.R is the received power, R is the responsivity of the
receiver, m is the optical modulation index per channel, and
.sigma..sub.N.sup.2 is the received noise power in the channel bandwidth.
The numerator is the received radio frequency (RF) power of any one
carrier. Because the signal is subcarrier multiplexed, each carrier is
given only a share of the threshold limited total swing of the optical
power. This sharing is described by the optical modulation index, m, given
by
##EQU2##
where P.sub.peakcarrier is the optical power when the carrier is at its
positive peak excursion, and P.sub.bias is the optical power corresponding
to the quiescent bias condition of the transmitter. If the assumption is
made that the carriers are mutually independent random signals, then the
sum of the carriers can be described as a Gaussian distributed stochastic
process. The normalized standard deviation of this sum is called the RMS
modulation index, .mu.. The expression for the RMS index for N channels is
##EQU3##
If .mu. is made too small, then the received electrical power is reduced.
If .mu. is made too large, then the probability that the laser will be
driven below threshold becomes considerable. Standard practice has been to
set the RMS modulation index to be 0.25 to 0.33, which is equivalent to
setting the clipping threshold 4 to 3 standard deviations away from the
mean of the signal distribution, respectively. For a numerical example, a
system that delivers 50 channels of AM video with a m of 0.25 would
require a received power of -9 dBm. (Assuming .sigma..sub.N.sup.2 =-106
dBm, m=0.05, and R=7.36 W.sup.1/2).
In addition to clipping, there are more nonlinear distortions that occur
during transmission. Directly modulated diode lasers have appreciable
nonlinearity, especially in the higher output power portion of their
characteristic and in the vicinity of their threshold. The modulation of
the laser can cause its emission to be chirped in wavelength. This can
cause distortion of the signal when it is transmitted through dispersive
fiber. The introduction of fiber amplifiers can increase distortions due
to chirp. Finally, the receiver will introduce its part to the total
nonlinearity of the link.
The received RF power can be increased by increasing the optical power,
increasing the RMS index, or the responsivity of the receiver. It is
unlikely that the responsivity can be meaningfully improved over current
values, and increasing .mu. has the undesirable side-effect of increasing
the clipping probability. Therefore, the only independent control on RF
signal power is received optical power. Unfortunately, optical sources
capable of handling analog signals are expensive on a dollar per watt
basis, and this puts a considerable premium on this method of CNR
improvement.
The noise power has several sources: relative intensity noise (RIN) of the
laser, shot noise of the light signal, thermal noise of the receiver, and
the excess noise of the electronics. The noise power is determined by the
quality of the components used and by universal constants of nature. The
quality of the components commonly used today are already at a level of
refinement that makes further improvement difficult and expensive. Because
cost is an important issue, especially in FTTH architecture, a reasonable
assumption is that the noise performance of the system is primarily fixed.
In fact, the expense of optical power and the irreducibility of the noise
power makes cost reduction difficult.
SUMMARY OF THE INVENTION
It is an object of the invention to address the above noted limitations of
the prior art. More specifically, it is an object of the invention to
provide an improved system and method for optical transmission of video
which does not require a substantially more complex receiver. It is an
additional object of the invention to provide an improved optical
transmission system for video signals which is backwards compatible with
most customer video equipment now in place. It is a further object of the
invention to provide improved optical transmission of video signals which
may be reproduced without objectionable artifacts and disturbances, and
that are indistinguishable from an NTSC standard signal.
In fulfillment of these objects, the present invention provides a method
and system in which the standard NTSC video is modified such that the
synchronization (sync.) signals are reduced in amplitude by a
predetermined amount, for example, by about 50%. This reduces the
distortion that the signal suffers when passed through a nonlinear
channel, such as an optical fiber network. This modulation is done in such
a way that requires no additional circuitry or equipment.
Other objects and features of the invention are made apparent from the
detailed description of preferred embodiments of the invention set forth
below.
BRIEF DESCRIPTION OF THE DRAWING
The present invention will be described with reference to the accompanying
drawing of which:
FIG. 1 is an illustration of out of band, in band visible, and in band
invisible distortion;
FIG. 2 is an illustration of a fifty channel, single octave, incoherent
NTSC video frequency plan;
FIG. 3 is an illustration of the distortion spectra that result from
quadratically phased coherent carriers;
FIG. 4 is an illustration of the histograms of signal voltage for
incoherent and quadratic phase coherent carrier systems;
FIG. 5 is an illustration of the signal voltage for incoherent and
quadratic phase coherent modulated carriers;
FIG. 6 is an illustration of the distortion spectra of incoherent and
quadratically phased coherent modulated carriers;
FIG. 7 is an illustration of a histogram of a NTSC signal with uniformly
distributed video information;
FIG. 8 is an illustration of the CTO spectra for coherent carriers with
random standard sync. pulses; and
FIG. 9 is a block diagram of an illustrative synchronized modulated sync.
pulse system in accordance with one embodiment of the invention.
DESCRIPTION OF THE INVENTION
Specific examples of the invention are now described below in reference to
the accompanying drawings. As made clear from these examples, the
invention advantageously employs a modified transmission format for NTSC
video. The term "modified" implies that the format is generally based on
the existing standards and that the additions or changes to that format
are small. For example, changing the carrier frequencies for transmission
would be a modification, while digitizing the signal for transmission
would not be a modification. The reason for this constraint is the first
requirement of modified format: The modified format should not require a
substantially more complex receiver.
The reason for this is economic. Any reduction in system cost due to format
change arises from the increased sharing of the transmitter. However, any
increased complexity in the receiver required by the new format will tend
to increase the system cost. Consider the following example. Suppose that
in the future, a FTTH system can use a $2,000 transmitter to drive 16
receivers (one per subscriber) that cost $100. The total per subscriber
cost is $225. If a format change allows the transmitter sharing to
increase by a factor of two, but also requires a receiver that is twice as
expensive, then the cost per line unit (LU) is $63 (transmitter)+$200
(receiver)=$263. The cost has gone up because the savings in the shared
transmitter are more than offset by the similar cost increase in the
non-shared receivers.
The second requirement stems from the desire for backwards compatibility
with most of the customer video equipment now in place. This is not an
easy task, because there are many older television sets that were
basically designed to work off-the-air with an antenna. There are also
several varieties of "cable-ready" televisions. This leads us to the
following statement of the second requirement for a modified signal
system: The signal delivered to the subscriber should be compatible with
any current cable-ready receivers. This requirement basically excludes the
consideration of older equipment. While this may seem to be deleterious to
the potential marketing of the service, it will not for the following
reasons. First, any "problem" receivers can be provisioned by using a
cable compatible tuner set top box (STB) This kind of device costs only
$50-$100, and is commonly rented to the cable subscriber for about
$1/month. Second, this exclusion is the basic policy of many cable
providers today. Therefore, the competitive market share and financial
impact of this requirement will be minimal.
The third requirement is one having to do with quality. This issue is very
complex, because beauty, or in this case image quality, is in the eye of
the beholder. The specifications for CNR, CSO, and CTO noted earlier
really do not give a complete description of image quality. These
specifications refer to certain measurements made with non-video modulated
test signals. They do not take into account the resulting visual patterns
produced by the noise or distortion. Certain types of noise may be very
disturbing, while others may be almost invisible, even though they result
in the same CNR measurement. For these reasons, the quality requirement
should be reinterpreted: The signal should produce an image and sound that
are free from objectionable artifacts and disturbances, and that are
indistinguishable from the NTSC standard signal.
A first possible modification to the NTSC transmission standard is simply
to change the carrier frequency assignments. It must be remembered that
the FCC standard assignments were intended for broadcasting, and had to
deal with previous frequency allocations and older technology limitations.
With the advent of broadband cable, there was a need to develop channel
plans that were more suited to cable systems. Currently, there are three
different plans which have been devised by the EIA/NCTA to accommodate the
wide bandwidth and contiguous allocation of television channels. There is
the standard plan, the incrementally related carrier (IRC) plan, and the
harmonically related carrier (HRC) plan. The standard plan leaves all the
VHF channels in their off-air locations. The IRC plan does this also
except for channels 5 and 6, which are shifted 2 MHz higher. The HRC plan
shifts all the channels down by 1.25 MHz from their IRC assignments.
Since these channel plans have become standardized, they satisfy the
compatibility requirement set forth above. There are still two questions
to be answered, though: which plan, and what channels to use. Both of
these questions require the consideration of distortion and how it
disturbs picture quality. If a set of unmodulated carriers are sent
through a link that has second and third order nonlinearity, a multitude
of frequency mixing products will be generated. These spurious frequencies
can be divided into three classes: out-of-band, in-band-visible, and
in-band-invisible.
This is illustrated in FIG. 1, where a hypothetical three carrier system is
shown (the vertical scale is in arbitrary units, A.U.). The carriers 11,
13, 15 are 8 MHz, 14 MHz, and 20 MHz, respectively, and each channel
extends 1.25 MHz below to 4.75 MHz above each carrier. Second and third
order distortion products, e.g., 17 and 19, respectively, appear in many
places in the band. Those that are below 6.75 MHz or above 24.75 MHz are
out-of-band type products. Products such as the 22 MHz second harmonic 17
are in-band-visible, because they fall in a channel and would produce a
strong visible signal. Products that fall exactly on carrier frequencies
potentially belong to the in-band-invisible class. These nonlinear
products will result in a zero to very low frequency modulation of the
channel involved, and if the carrier frequencies are stable and precise
these products will be practically invisible to the viewer. This results
in a 5 to 10 dB power improvement in apparent distortion performance.
The ideal channel plan would be such that all the intermodulation products
fall either out of band or are invisible. The plan that best satisfies
this criterion is the HRC plan with a channel line-up that occupies less
than a single octave. Let us assume that 50 channels are desired, and that
the lowest frequencies possible should be used. This would result in using
harmonics 50 through 99 as the carriers. The resulting multicarrier
signal, V(t) , can then be written as a finite sum involving the channel
signals S.sub.i (t), the channel spacing frequency, .omega..sub.0, and the
carrier phases, .phi..sub.i.
##EQU4##
The operation of such a scheme is diagrammed in FIG. 2, where the
fundamental, CSO, and, CTO spectra 21, 23, 25 are plotted for the case of
unmodulated carriers. The amplitudes of the CSO and CTO, in this FIG. and
all the following FIG.s, are each normalized by a constant factor so that
they can be plotted on the same scale as the fundamental. In practice, the
distortion products would be much lower in amplitude. Note that all the
CSO components fall either below or above the single octave band, showing
that single octave systems completely avoid CSO. The CTO spectrum
unfortunately peaks right in the center of the fundamental band; however,
all the distortion products fall exactly upon the carrier frequencies.
Thus, by the mechanism described above, they will impair the signal less.
Furthermore, if the CSO and the CTO are of comparable magnitude, as they
are in most systems, then we could conceivably allow the CTO power to
become 3 dB larger without reducing visual quality because we have
eliminated the CSO. This shifting of specification margin would have to be
justified with actual subjective image quality studies.
The spectra given in FIG. 2 were computed assuming that the carriers are
all incoherent (randomly phased in time) with respect to one another. When
this is the case, the power of each distortion product can be added to
find the total power at a particular frequency. However, because the
carrier phases, .phi..sub.i, are now random variables, this spectrum is
only an average power distribution. There will be times when the phases
drift in such a way to produce strong coherence, and at these times the
distortion will be much worse. This time-varying distortion behavior would
be difficult to predict and control, and would produce objectionable
visual interference.
In fact, one cannot have a strict HRC system where the carriers are
incoherent. The phase of a carrier is simply the time integral of the
instantaneous frequency of the carrier. If the carrier frequencies are
exactly harmonically locked together, then it follows that their phases
are locked together in a fixed relationship. While the initial phase
relationship may have been random over frequency, it remains fixed over
time. In other words, the phases are perfectly time correlated; they are
not time-random, and thus do not satisfy the incoherent assumption
referred to above.
What is needed is some set of carrier phases such that the coherent sum of
all the distortion products is minimized. Several such systems have been
proposed, but the simplest arrangement is the so called Newman phases. The
phases are set so that the phase of each carrier is quadratically
dependent on the carrier harmonic number, written as,
##EQU5##
This phasing has been shown numerically to reduce the peak value of the
multicarrier signal. It therefore produces low distortion. This can be
seen in FIG. 3, where the CSO 31 and CTO 33 of the quadratic phase system
is shown. The distortion is lower than the incoherent case, the average
improvement being 3 dB (amplitude), while at the same time the distortion
is constant in time and thus less visible.
The results above assume that the transmission link transfer function can
be characterized by a power series expansion. In the case of analog
optical, this is only true for signals that remain within the operating
region of the laser. When the signal drives the laser below threshold, the
optical signal cannot follow, and clipping distortion results. This kind
of impairment can be studied by considering the distribution of the
multicarrier signal. The distributions for the incoherent case 41 and the
quadratically phased coherent case 43 are compared in FIG. 4.
One can see that in the incoherent case 41, the distribution is almost
Gaussian, as one would expect from a sum of independent random variables.
The standard practice is to adjust the dynamic range of the signal so that
the laser threshold occurs at a point 3 to 4 standard deviations out on
one side of this Gaussian distribution. Even doing this, the carrier sum
will occasionally get clipped. The coherent distribution, on the other
hand, is much more compact and uniform. Furthermore, it does not have any
extensive wings. This would enable the increase of the dynamic range of
the carrier by 2.2 to 3.4 dB (amplitude) while at the same time
eliminating all occurrences of clipping. It is also interesting to note
that the histogram of the signal is asymmetric and unevenly distributed.
Both of these unique features result from the deterministic properties of
the quadratically phased carriers.
All of the preceding examples involve unmodulated carriers. To compute the
effects of video modulation, the channel signals will be assumed to be
unsynchronized and to have visual signals that are uniformly distributed
random variables. Assuming that the many different signals arrive from
diverse sources, then the signals are uncorrelated in time. Computing the
distributions of signal level for the modulated case yields the results in
FIG. 5. Note that the incoherent signal 51 has remained Gaussian, but its
variance has been reduced markedly. This effect is a direct consequence of
the modulation reducing the average signal level. The distribution for the
coherent, quadratic phase signal 53 has become narrower in variance, but
has unfortunately become slightly larger in total extent. Modulation
causes this slight degradation because some of the carriers are reduced to
low levels while others are still high. When this happens, the
cancellation that occurs almost perfectly in the unmodulated case is
incomplete. This results in momentary peaks in the signal. However, the
coherent signal is still less widely distributed than the incoherent
signal, and it would have approximately 1 to 2 dB (amplitude) advantage
over the incoherent system in terms of clipping penalty.
In terms of distortion the average CTO spectrum for the incoherent 61 and
phase coherent 63 cases with modulation are shown in FIG. 6. The average
improvement in CTO of the coherent quadratic phased single octave HRC
system and the random phased incoherent single octave HRC systems, both
with modulation, is 1.7 dB (amplitude).
From the analysis above, video modulation has a strong influence on both
the distortion and the clipping behavior of the multicarrier signal. Thus,
it may be possible to modify the modulation format so that the distortion
and clipping behavior is enhanced. Such a technique is now described in
reference to FIGS. 7 to 9.
The amplitude distribution of an NTSC signal is illustrated in FIG. 7,
which is a histogram of a NTSC signal with uniformly distributed video
information. The low, uniform part 71 of the distribution is the actual
video information, whereas the high, sharp elements 73 represent the
synchronization part of the signal. The sync. signals 73 are the highest
amplitude elements of the signal, and as such are a significant source of
distortion. For this reason, modifying the sync. part of the signal has
the greatest potential for providing some distortion improvement.
Normally, the individual channels in an ensemble are all frame random, that
is, the video frame phases are uncorrelated. Thus, a first change is to
synchronize all the channels together on a frame by frame basis. By doing
this, all the video signals would be in the sync. interval at the same
time. If this is done, then the total distortion power is actually worse
than the frame random case, as shown in FIG. 8 (illustrating the CTO
distortion spectra for coherent carriers with random standard sync. pulses
81, synchronized standard sync. pulses 83, and synchronized modulated
sync. pulses 85). However, most of the distortion is occurring during the
sync. period, and so would not produce spurious patterns in the video.
Such distortion could produce incorrect black level, frame jitter, and
color matching problems through interference with the synchronizing
signals of the video.
Therefore, locking all the video channels together in sync. can affect
distortion levels. Because the video programming on a typical system comes
from many different independent sources, the feed signals will not be
synchronized. This can be resolved by directing the feed video streams
into a four field buffer. Each stream can then be delayed by the
appropriate time so that they are all brought into synchronism.
Because the sync. signal does effect the distortion, real improvement can
be had by modifying the NTSC synchronization signal. It should be noted
that the duration, bandwidth, and signal level of the sync. signal was
chosen partly to make the construction of receivers cheap and simple, and
partly to cope with a noisy and uncertain wireless transmission medium.
For these reasons, the information density of the sync. signal is very
low, and compression of this portion of the signal is possible.
The invention realizes this compression by reducing the gain of the
transmitter RF amplifier by 3 dB (amplitude) during the sync. period,
while simultaneously increasing the RF gain of the receiver by a similar
amount. An example of such a system that would do this for frame
synchronized channels is diagrammed in FIG. 9.
In FIG. 9, a plurality of video sources 92 provide respective video signals
to a video synchronizer 94. The video synchronizer 94 delays the received
video signals by an appropriate time to bring each signal into
synchronism. The video synchronizer 94 generates an output baseband video
signal and a sync. signal. These signals are provided as shown to an
adjustable gain RF amplifier 98.
In addition to the video signals on the optical link, a pilot tone
generator 96 produces a "constant" pilot tone that is used for automatic
gain control (AGC) of the adjustable gain amplifier 98. When the sync.
period is detected, the gain of the adjustable gain RF amplifier 98 is
reduced. This reduces the signal levels and thus relieves the distortion.
Because the pilot tone shares the RF amplifier 98, it is also reduced in
amplitude.
The modulated signal output from the adjustable gain amplifier 98 is
converted to an optical format with E/O converter circuit 91 and then
transmitted through the optical fiber network 93. The signal arrives at
the receiver, which in this example, comprises O/E converter circuit 95,
pilot receiver circuit 97, and adjustable gain amplifier 99.
The modulated signal is received by O/E converter 95 which converts the
optical signal into an electrical signal. Pilot receiver 97 detects the
pilot tone portion of the received signal and produces an adjustable gain
control (AGC) signal in response thereto. The AGC signal adjusts the gain
of a second adjustable gain amplifier 99, thereby detecting the decline in
power during the sync. period and forcing a gain increase suitable to
recover the original signal. This compression can be accomplished easily
because all of the channels are locked in frame synchronism. This enables
the multichannel to be processed in bulk, cheaply, by a single modulation
amplifier.
Using this method of sync. modulation, the resulting distortion spectrum,
as shown in FIG. 8, is reduced by 3.5 dB (amplitude) when compared with
normal sync. video. The cost of this improvement is that the SNR of the
sync period would be degraded by 6 dB (power). However, the sync. portion
of the typical modern receiver is very immune to noise through the use of
phase locked loop (PLL) technology. Also, because of the digital nature of
the sync. signal, there is a threshold SNR, and thus the 6 dB reduction in
SNR shall not have any effect on received quality.
The cost in terms of equipment for sync. modulation is minimal. The pilot
tone AGC circuitry is not complicated or expensive to implement, and in
fact is typically already present to correct for the linear
characteristics of the optical link. Similar arguments apply to the sync.
detector and gain modulator needed at the transmitter.
It is noted that the method according to the invention bears a superficial
resemblance to some of the simple "video scrambling" methods used in cable
television for many years. The motivation for scrambling is to control
access to certain select channels. In these systems, the sync. portion of
the individual channel to be scrambled is shifted down by approximately
0.5 times the full range of the video signal. This shifting is done to the
signal while it is a baseband video signal and before it is placed on its
RF carrier. The signal then requires a special descrambler device to
recover the original signal. This descrambler works by first demodulating
the scrambled signal to a baseband video format, then shifting the sync.
portion back up to its correct level.
The invention described herein is different because 1) the motivation is to
reduce distortion, not interdict channels; 2) the sync. signal is
modulated (multiplied), not shifted; 3) the sync. modulation occurs to all
the channels in the ensemble, not selected ones; 4) the sync. modulation
is done in the RF domain, not at baseband; 5) there is no need for any
additional equipment, no descramblers.
In summary, the synchronization pulse modulation method described herein
operates by reducing the transmitted power during the synchronization
intervals in the NTSC signal. Assuming that the carried channels are all
frame synchronous, this kind of signal is easily recovered, and thus this
method will not add significant cost to the receiver. By modulating the
sync. pulses, the distortion is reduced by an additional 3.5 dB
(amplitude). This would result in an optical modulation index (OMI)
increase of 1.2 dB. Thus, by changing the transmission standards in a
backward compatible way, small but meaningful increases in the OMI can be
made.
The improvements obtained with the present invention are even more
significant when combined with the above described single octave
harmonically related carrier frequency assignment method and the coherent
quadratic phase assignment method. For example, I have found that the
total improvement in OMI that can be had using these methods is 3.8 dB.
For FTTH, this would reduce the required power at the subscriber by 3.8
dB, and therefore result in a two-fold increase in transmitter sharing.
The invention has now been described by reference to preferred embodiments,
in fulfillment of the objects of the invention. These embodiments have
been set forth merely as examples. Variations and modifications will be
apparent to those skilled in the art without departing from the spirit and
scope of the invention.
* * * * *
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