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| United States Patent |
6,359,941
|
|
den Bakker
|
March 19, 2002
|
System and method for improved reference threshold setting in a burst mode
digital data receiver
Abstract
A system and method for automatically setting an advantageous reference
threshold in a burst mode receiver to reduce the burst mode penalty
associated with prior art burst mode optical data transmissions, and to
reduce duty cycle distortion at the receiver output. In a preferred
embodiment, the maximum excursion of a received data signal is compared to
an offset threshold equal to approximately twice the offset voltage
supplied by an offset generator. If the data signal amplitude is less than
the offset threshold, then the reference threshold voltage is set
approximately equal to the offset voltage. If, on the other hand, the data
signal amplitude is greater than or approximately equal to the offset
threshold, then the reference threshold is set to one-half of the
difference between the maximum and minimum excursions of the data signal
(i.e. the difference amplitude). In another embodiment of the invention,
the reference threshold is set to a fractional value of the sum of the
difference amplitude and the offset voltage. The fractional value is
selected so that the reference threshold is approximately equal to
one-half of the difference amplitude. An optional selector enables
selective variation of the fractional value to compensate for changes in
the offset voltage in order to maintain the reference threshold at the
optimal value of approximately one-half of the difference amplitude.
| Inventors:
|
den Bakker; Ton (Barneveld, NL)
|
| Assignee:
|
Lucent Technologies Inc. (Murray Hill, NJ)
|
| Appl. No.:
|
070049 |
| Filed:
|
April 30, 1998 |
| Current U.S. Class: |
375/317 |
| Intern'l Class: |
H04L 025/00 |
| Field of Search: |
375/316,317,318
359/189
|
References Cited [Referenced By]
U.S. Patent Documents
| 5430766 | Jul., 1995 | Ota et al. | 375/318.
|
Primary Examiner: Pham; Chi
Assistant Examiner: Burd; Kevin M
Claims
I claim:
1. A system for setting a reference threshold in a burst mode receiver
having an input and an output for receiving, in intermittent bursts
through the input, a digital data signal having a minimum and a maximum
excursion, comprising:
offset generator, connected to the receiver input, that applies an offset
voltage of a predefined amplitude to the data signal, said predefined
amplitude being sufficient to generate a substantially null output signal
at the receiver output when no data signal is received at the receiver
input, to thereby reduce noise distortion effects at the output of the
receiver; and
signal processor, connected to said offset generator and to the receiver
output, that:
derives a difference amplitude by determining a difference between the
maximum and minimum signal excursions;
compares the difference amplitude to an offset threshold, the offset
threshold being substantially equal to twice the offset voltage predefined
amplitude, and
(i) when the difference amplitude is less than the offset threshold, sets
the reference threshold substantially equal to the offset voltage, so that
the reference threshold is substantially equivalent to the null output
signal at the output of the receiver, and
(ii) when the difference amplitude is one of substantially equal to and
greater than the offset threshold, sets the reference threshold
substantially equal to approximately one-half of the difference amplitude.
2. The system of claim 1, further comprising a transimpedance preamplifier
connected between the receiver output and said offset generator for
amplifing the data signal in accordance with a first predetermined
amplification magnitude.
3. The system of claim 1, further comprising an output amplifier connected
between said signal processor and the receiver output for amplifying the
data signal in accordance with a second predetermined amplification
magnitude.
4. The system of claim 1, wherein said signal processor comprises:
a positive peak detector having an output, for detecting the maximum
excursion of the data signal;
a negative peak detector having an output, for detecting the minimum
excursion of the data signal, wherein the difference amplitude is
determined by combining outputs of said respective positive and negative
peak detectors; and
a resistor network, connected to said respective positive and negative peak
detector outputs, for generating a output value substantially equivalent
to one-half of the difference amplitude.
5. The system of claim 4, further comprising:
first reset circuit, connected to said positive peak detector, for
discharging said positive peak detector at an end of the data signal
burst; and
second reset circuit, connected to said negative peak detector, for
charging said negative peak detector at the end of the data signal burst,
so that said positive and negative peak detectors are prepared for
receiving a next data signal burst.
6. A method for setting a reference threshold in a burst mode receiver,
having an input and an output for receiving, in intermittent bursts
through the input, a digital data signal having a minimum and a maximum
excursion, comprising the steps of:
(a) applying, by an offset generator connected to the receiver input, an
offset voltage of a predefined amplitude to the data signal, said
predefined amplitude being sufficient to generate a substantially null
output signal at the receiver output when no data signal is received at
the receiver input, to thereby reduce noise distortion effects at the
output of the receiver;
(b) deriving, in a signal processor connected to the offset generator and
to the receiver output, a difference amplitude by determining a difference
between the maximum and minimum signal excursions;
(c) comparing, in the signal processor, the difference amplitude to an
offset threshold, the offset threshold being substantially equal to twice
the offset voltage predefined amplitude; and
(d) when the difference amplitude is less than the offset threshold,
setting, by the signal processor, the reference threshold substantially
equal to the offset voltage, so that the reference threshold is
substantially equivalent to the null output signal the output of the
receiver; and
(e) when the difference amplitude is one of substantially equal to and
greater than the offset threshold, setting, by said signal processor, the
reference threshold substantially equal to one half of the difference
amplitude.
7. The method of claim 6, further comprising the step of:
(f) prior to said step (a) amplifying, in a transimpedance preamplifier
connected between the receiver output and the offset generator, the data
signal in accordance with a first predetermined amplification magnitude.
8. The method of claim 6, further comprising the step of:
(f) after said step (e), amplifying in an output amplifier connected
between the signal processor and the receiver output, the data signal in
accordance with a second predetermined amplification magnitude.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to digital data receivers for
receiving burst mode digital data, and more particularly to a system and
method for reducing the burst mode penalty and output signal duty cycle
distortion suffered by the receiver during digital data transmissions by
automatically selecting an advantageous reference threshold.
2. Description of the Related Art
Digital optical communication between modem computer systems may be
accomplished using either continuous or burst mode data transmissions.
Conventional AC-coupled optical receivers are typically used for
continuous data transmissions, while DC-coupled optical receivers are used
for burst mode transmissions. Passive optical networks utilizing burst
mode data transmission have proliferated in recent years. Because
AC-coupled receivers are generally superior in sensitivity and performance
to DC-coupled receivers, attempts have been made to adapt AC-coupled
receivers for use with burst mode data transmissions. Typically this has
been accomplished by encoding burst mode transmitted data to enable an
AC-coupled receiver to interpret and process the transmissions. However,
in passive optical networks the transmission media must be shared by
several users--each user is allowed to transmit in a dedicated time slot
only and is required to be "silent" outside the dedicated time slot. Thus,
data encoding is not possible in passive optical networks because an
encoded data signal would not exhibit the required time slot information.
DC-coupled receivers that receive burst mode data transmissions suffer from
a decrease in sensitivity and signal power that is often referred to as a
"burst mode penalty". Typically, by the time a digital data signal is
received by a DC-coupled receiver, the signal pulse shapes are degraded to
an analog-type pulse shapes having uncertain amplitudes. In previously
known DC-coupled receivers, the digital data signal is compared to a fixed
reference threshold voltage in a decision circuit of the receiver to
recover the pure digital signal. Thus, when uncertain and widely varying
signal amplitudes are compared to the fixed reference threshold voltage,
identification of logic ONEs and ZEROes is erratic and results in a high
burst mode penalty and distortion. Accordingly, in recent years attempts
have been made to develop techniques to improve the ability of a
DC-coupled receiver decision circuit to identify logic ONEs and ZEROEs
with greater certainty to improve receiver performance characteristics. In
particular, industry efforts have been directed to reducing the burst mode
penalty.
One such technique, described in U.S. Pat. No. 5,025,456 to Ota et al.,
provides a DC-coupled receiver with adaptive threshold circuitry for
providing a varying reference threshold voltage that adapts to the
amplitudes of the received digital data signal. The reference threshold
voltage amplitude is set to one half of the minimum and maximum excursion
of the data signal. Thus, the reference threshold voltage automatically
follows the changes of amplitudes in the data signal and provides improved
identification of logic ONEs and ZEROes, resulting in a significant
reduction in the burst mode penalty suffered by the DC-coupled receiver.
However, the adaptive threshold approach suffers from a significant
disadvantage. All digital data receivers are subject to noise that is
generated by a variety of internal and external sources. Thus, one of the
requirements in a DC-coupled burst mode receiver is that the receiver
output must be "silent", i.e. at zero amplitude without a signal at the
input of the receiver, to reduce or eliminate the noise. This is
functionally accomplished by applying an extra offset voltage at the
threshold level of sufficient amplitude to overcome the input and internal
noise. Accordingly, the adaptive threshold is actually a sum of the offset
voltage amplitude and one half of the difference between the maximum and
minimum excursions of the received data signal. Thus, the reference
threshold level is not actually in the desirable middle position between
the maximum and minimum excursions of the data signal, but is then always
above the middle position. As a result, a DC-coupled receiver equipped
with adaptive threshold circuitry still suffers from degradation in
sensitivity/signal power (i.e. burst mode penalty) of at least 3 dB.
Another disadvantage of the adaptive threshold approach is that
significant duty cycle distortion is present at the receiver output when
low amplitude data signals are received at the receiver input.
Thus, it would be desirable to provide a DC-coupled receiver with the
ability to automatically set an advantageous reference threshold that
reduces the burst mode penalty suffered by the receiver and that reduces
duty cycle distortion at the receiver output when low amplitude data
signals are received at the receiver input.
SUMMARY OF THE INVENTION
In accordance with the present invention, a system and method for
automatically setting an advantageous reference threshold in a burst mode
receiver to reduce the burst mode penalty associated with burst mode
optical data transmissions, and to reduce duty cycle distortion at the
receiver output, are provided.
The system of the present invention is implemented in a burst mode digital
data receiver having an input and an output. The system includes an
optional transimpedance preamplifier, connected to the receiver input, for
amplifing a received digital data signal; an offset generator, connected
to the preamplifier, for generating an offset voltage of sufficient
amplitude to eliminate noise at the receiver output, when the data signal
is absent at the receiver input; a signal processor, connected to the
offset generator, for automatically setting the reference threshold
voltage to an advantageous value in accordance with the invention; and an
optional output amplifier connected to the preamplifier and the signal
processor for amplifying the digital data signal before the signal is
processed by other receiver circuitry.
In a preferred embodiment of the invention, the signal processor compares
the amplitude (i.e. maximum excursion) of the received data signal to an
offset threshold equal to approximately twice the offset voltage
amplitude. If the data signal amplitude is less than the offset threshold,
then the signal processor sets the reference threshold voltage
approximately equal to the offset voltage. If, on the other hand, the data
signal amplitude is greater than or approximately equal to the offset
threshold, then the signal processor sets the reference threshold to
exactly one half of the difference between the maximum and minimum
excursions of the data signal. Thus, when the data signal amplitude is
very low (i.e. lower than twice the offset voltage amplitude) the data
signal is assumed to be generated by noise and the reference threshold at
the output will be substantially equal to the offset voltage, producing a
silent receiver output. When, on the other hand, the data signal
substantially equals or exceeds the offset threshold, the reference
threshold is set to exactly one-half of the maximum and minimum excursions
of the data signal, without the addition of the offset voltage to the
threshold as is done in the previously known adaptive threshold approach.
This arrangement virtually eliminates the burst mode penalty, thus
improving receiver sensitivity, and furthermore eliminates duty cycle
distortion.
In another embodiment of the invention, the signal processor sets the
reference threshold to a fractional value of the following expression:
[(maximum data signal excursion-minimum data signal excursion)+offset
voltage]
The fractional value is selected so that the resulting reference threshold
is approximately equal to one-half of the difference between the maximum
and minimum excursions of the data signal. As a result, the reference
threshold is set to the desirable mid-point position between the maximum
and minimum excursions without the undesirable addition of the offset
voltage to the threshold as in the previously known adaptive threshold
approach. Optionally, a selector may be connected to the signal processor
to enable selective variation of the fractional value to compensate for
changes in the offset voltage.
Other objects and features of the present invention will become apparent
from the following detailed description considered in conjunction with the
accompanying drawings. It is to be understood, however, that the drawings
are designed solely for purposes of illustration and not as a definition
of the limits of the invention, for which reference should be made to the
appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
In the drawings, wherein like reference characters denote corresponding or
similar elements throughout the various figures:
FIG. 1 is a schematic block diagram of a reference threshold setting system
used in a burst mode digital data receiver in accordance with the present
invention;
FIG. 2 is an exemplary block diagram of a signal processor of a preferred
embodiment of the reference threshold setting system of FIG. 1 in
accordance with the present invention; and
FIG. 3 is an exemplary block diagram of a signal processor of a second
embodiment of the reference threshold setting system of FIG. 1 in
accordance with the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The system and method of present invention are described herein with
reference to common electronic components such as preamplifiers, voltage
generators, peak detectors, clock/data recovery circuits, and amplifiers
that are well known in the art. Accordingly, the construction of the
electronic components of the invention need not be discussed in detail and
such components will be described only with respect to their
functionality.
Referring now to the drawings, and initially to FIG. 1 thereof, a reference
threshold setting system 10 is shown. The reference threshold setting
system 10 is preferably implemented in a burst mode digital data receiver
5, having an outside input 6 for receiving a digital data signal having a
maximum and a minimum excursion, and an output 7 that is connected to a
receiver component system 8. The component system 8 may include a
clock/data recovery circuit, an amplifier and other typical receiver
components (not shown).
The system 10 includes an input signal line 12 for receiving the data
signal from the receiver outside input 6, an optional transimpedance
preamplifier 14 for amplifying the received data signal, an offset
generator 16, connected to the preamplifier 14, for generating an offset
voltage of sufficient amplitude to eliminate noise at an output signal
line 22 (connected to the component system 8) when the data signal is
absent at the input signal line 12, a signal processor 18, connected to
the offset generator 16, for analyzing the data signal and for setting an
advantageous reference threshold voltage for application to the data
signal, and an optional output amplifier 20, connected to the preamplifier
14, the signal processor 18 and the output signal line 22, for amplifying
the digital data signal before the signal is passed via the output signal
line 22 to the component system 8 for further processing.
In a preferred embodiment of the invention the signal processor 18 detects
the maximum and minimum excursions of the data signal, determines the
difference between the maximum and minimum excursions (hereinafter the
"difference amplitude") of the received data signal and compares the
difference amplitude to an offset threshold that is equal to approximately
twice the offset voltage amplitude generated by the offset generator 16.
If the difference amplitude is less than the offset threshold, then the
signal processor 18 sets the reference threshold voltage approximately
equal to the offset voltage. If, on the other hand, the difference
amplitude is greater than or approximately equal to the offset threshold,
then the signal processor sets the reference threshold to exactly one-half
of the difference amplitude before applying the reference threshold to the
output amplifier 20. Thus, when the difference amplitude is very low (i.e.
lower than twice the offset voltage amplitude), the data signal is assumed
to be generated by noise and the reference threshold at the output
amplifier 20 will be substantially equal to the offset voltage, producing
a silent receiver output due to the offset voltage applied by the offset
generator 16. When, on the other hand, the difference amplitude
substantially equals or exceeds the offset threshold, the reference
threshold is set to exactly one-half of the difference amplitude, without
the addition of the offset voltage to the threshold as in the previously
known adaptive threshold approach. This arrangement virtually eliminates
the burst mode penalty thus improving receiver sensitivity, and
furthermore eliminates duty cycle distortion.
FIG. 2 depicts an exemplary signal processor 18 in accordance with a first
embodiment of the invention. The signal processor 18 includes a two input
positive peak detector 26 for detecting the maximum excursion of the data
signal, a negative peak detector 28 for detecting the minimum excursion of
the data signal, and a resistor network 30 for setting the reference
threshold equal to one half of the total output (i.e. the difference
amplitude) of the two input positive peak detector 26 and the negative
peak detector 28. The first input of the two input positive peak detector
26 is connected to the offset generator 16, while the second input is
connected to the output of the negative peak detector 28. The output of
the two input positive peak detector 26 is connected to the resistor
network 30. The input of the negative peak detector 28 is connected to the
offset generator 16, while the output is connected to the resistor network
30. The output of the resistor network 30 is connected to the output
amplifier 20. Preferably, the offset generator 16 supplies a negative
offset voltage to the first input of the two input positive peak detector
26, and a positive offset voltage of equivalent amplitude to the input of
the negative peak detector 28. Optionally, a reset circuit 32 may be
connected to the output of the two input positive peak detector 26, and a
reset circuit 34 may be connected to the output of the negative peak
detector 28, for discharging the two input positive peak detector 26 and
for charging the negative peak detector 28, respectively, at the end of a
data signal burst.
Because the minimum excursion of the data signal is typically zero, the
difference amplitude is typically substantially equal to the maximum
excursion of the data signal; thus, the negative peak detector 28 outputs
the amplitude of the positive offset voltage generated by the offset
generator 16. The two input positive peak detector 26 outputs the maximum
excursion of the highest of its two inputs. One input of the resistor
network 30 detects the maximum amplitude of the output of the negative
peak detector 28 (i.e. the positive offset voltage), the other input
detects the amplitude of a sum of the maximum excursion of the data signal
and the negative offset voltage. When the data signal maximum excursion is
substantially equal to or lower than twice the amplitude of the offset
voltage, both the two input positive peak detector 26 and the negative
peak detector 28 output the positive offset voltage to the resistor
network 30. Halving the total output of the peak detectors 26 and 28, the
resistor network 30 produces a reference threshold voltage at the output
amplifier 20 that is substantially equivalent to the positive offset
voltage. When on the other hand, the data signal maximum excursion is
substantially equal to or above twice the offset voltage amplitude, the
two input peak detector 26 outputs the data signal maximum excursion (or
the difference between the maximum and minimum excursions of the data
signal when the minimum excursion is not zero) added with the negative
offset voltage to the resistor network 30. The total output of the peak
detectors 26 and 28 is then the data signal maximum excursion (or the
difference between the maximum and minimum excursions of the data signal
when the minimum excursion is not zero) because the negative offset
voltage portion at the output of the two input peak detector 26 cancels
out the positive offset voltage output of the negative peak detector 28.
Halving the total output of the peak detectors 26 and 28, the resistor
network 30 produces a reference threshold voltage at the output amplifier
20 that is substantially equivalent to one-half of the data signal maximum
excursion (or one-half of the difference between the maximum and minimum
excursions of the data signal when the minimum excursion is not zero).
In another embodiment of the invention, the signal processor 18 sets the
reference threshold to a fractional value or part of the sum of the
difference amplitude and the offset voltage. The fractional value is
selected so that the reference threshold is approximately equal to
one-half of the difference amplitude. A exemplary fractional value for a
typical offset voltage may be between 30% and 40%. As a result, the
reference threshold is set by the signal processor 18 to the desirable
approximate middle position, or mid-point between the maximum and minimum
excursions without the undesirable addition of the offset voltage to the
threshold as in the previously known adaptive threshold approach.
Optionally, a selector 24 may be connected to the signal processor 18 to
enable selective variation of the fractional value to compensate for
changes in the offset voltage.
An exemplary signal processor 18' of this alternate embodiment of the
invention is shown in FIG. 3. The signal processor 18' includes a positive
peak detector 36, having an input connected to the offset generator 16,
for detecting the maximum excursion of the data signal, a negative peak
detector 38, having an input also connected to the offset generator 16,
for detecting the minimum excursion of the data signal, and a resistor
network 40, connected to the outputs of the positive peak detector 36 and
the negative peak detector 38, for setting the reference threshold equal
to a fractional value of one-half of the total output (i.e. the sum of the
difference amplitude and the offset voltage amplitude) of the positive
peak detector 36 and the negative peak detector 38. Optionally, a reset
circuit 42 may be connected to the output of the positive peak detector
36, and a reset circuit 44 may be connected to the output of the negative
peak detector 38, for discharging the positive peak detector 36 and for
charging the negative peak detector 38, respectively, at the end of a data
signal burst. Because the minimum excursion of the data signal is
typically zero, the negative peak detector 38 outputs the amplitude of the
offset voltage generated by the offset generator 16. The positive peak
detector 36 outputs the maximum excursion of the data signal. The resistor
network 40 then receives the sum of the maximum excursion and the offset
voltage amplitude and sets the reference threshold to a predetermined
fractional value or part of the sum.
Because typical offset voltages used in burst mode receivers are known in
advance, the fractional multiplier applied to the sum to determine the
fractional value is selected so that the reference threshold is
approximately equal to one half of the difference amplitude. For typical
offset voltages, the fractional value may be set between about 30% and 40%
of the sum. The resistor network 40 may be implemented in a variety of
ways. For example, the resistor network 40 may comprise a set of two
resistors (not shown), with respective values of R1 and R2, arranged in
series between the outputs of the positive peak detector 36 and the
negative peak detector 38. To produce a particular fractional value, R1
and R2 may be varied in accordance with the following expression:
fractional value =R2/(R1+R2). For example, for a fractional value of 50%,
or 0.5 (as in the above described adaptive threshold technique), R1 is
equal to R2. The optional selector 24 can operatively vary the values of
R1 and R2 to produce different fractional values in order to compensate
for changes in the offset voltage.
Thus, while there have shown and described and pointed out fundamental
novel features of the invention as applied to preferred embodiments
thereof, it will be understood that various omissions and substitutions
and changes in the form and details of the devices illustrated, and in
their operation, may be made by those skilled in the art without departing
from the spirit of the invention. For example, it is expressly intended
that all combinations of those elements and/or method steps which perform
substantially the same function in substantially the same way to achieve
the same results are within the scope of the invention. It is the
intention, therefore, to be limited only as indicated by the scope of the
claims appended hereto.
* * * * *
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