AD AD805BN

Data Retiming
Phase-Locked Loop
AD805*
a
FEATURES
155 Mbps Clock Recovery and Data Retiming
Permits CCITT G.958 Type A Jitter Tolerance
Permits CCITT G.958 Type B Jitter Transfer
Random Jitter: 0.68 rms
Pattern Jitter: Virtually Eliminated
Jitter Peaking: Fundamentally None
Acquisition: 30 Bit Periods
Accepts NRZ Data without Preamble
Single Supply Operation: –5.2 V or +5 V
10 KH ECL Compatible
OBS
CLOCK RECOVERY AND
DATA RETIMING APPLICATION
DATA
INPUT
VOLTAGE
CONTROLLED
PHASE
SHIFTER
PHASE
DETECTOR
RETIMING
MODULE
RECOVERED
CLOCK
RETIMED
DATA
OLE
The AD805 is a data retiming phase-locked loop designed for
use with a Voltage-Controlled Crystal Oscillator (VCXO) to
perform clock recovery and data retiming on Nonreturn to Zero
(NRZ) data. The circuit provides clock recovery and data
retiming on standard telecommunications STS-3 or STM-1
data (155.52 Mbps). A Vectron C0-434Y Series VCXO circuit
is used with the AD805 for specification purposes. Similar
circuit performance can be obtained using other commercially
available VCXO circuits. The AD805-VCXO circuit used for
clock recovery and data retiming can also be used for large
factor frequency multiplication.
The AD805-VCXO circuit meets or exceeds CCITT G.958
regenerator specifications for STM-I Type A jitter tolerance and
STM-1 Type B jitter transfer. The simultaneous Type A, wideband jitter tolerance and Type B, narrow-band jitter transfer
allows the use of the AD805-VCXO circuit in a regenerative
application to overcome optical line system interworking limitations based on signal retiming using Type A passive tuned
device technology such as Surface-Acoustic-Wave (SAW) or
dielectric resonator filters, with Type B active devices such as
Phase-Locked Loops (PLLs).
The circuit VCXO provides a stable and accurate clock frequency signal with or without input data. The AD805 works
with the VCXO to dynamically adjust the recovered clock frequency to the frequency associated with the input data. This
frequency control loop tracks any low frequency component of
jitter on the input data. Since the circuit uses the VCXO for
clock recovery, it has a high Q for excellent wideband jitter attenuation. The jitter transfer characteristic of the circuit is within the jitter transfer requirements for a CCITT G.958 STM-1
Type B regenerator, which has a corner frequency of 30 kHz.
The AD805 overcomes the higher frequency jitter tolerance
limitations associated with traditional high Q, PLL based clock
and data recovery circuits through the use of its data retiming
loop. This loop, made up of the AD805’s voltage-controlled
*Protected by U.S. Patent No. 5,036,298
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
GAIN
VCXO
(EXTERNAL)
AD805
PRODUCT DESCRIPTION
LOOP
FILTER
phase shifter, phase detector, and loop filter, act to align input
data phase errors to the stable recovered clock provided by the
VCXO. The range of the voltage-controlled phase shifter, at
least 2 Unit Intervals (UI), and the bandwidth of this loop, at
roughly 3 MHz, provide the circuit with its wideband jitter
tolerance characteristic.
TE
The circuit can acquire lock to input data very quickly, within
44 bit periods, due to the accuracy of the VCXO and the action
of the data retiming loop. Typical integrated second-order PLLs
take at least several thousand bit periods to acquire lock. This is
due to their having a wide tuning range VCO. Decreasing the
loop damping of a traditional second-order PLL shortens the
length of the circuit’s acquisition time, but at the expense of
greater jitter peaking.
The AD805-VCXO circuit is a second- order PLL that has no
jitter peaking. The zero used to stabilize the control loop of the
traditional second-order PLL effects the closed-loop transfer
function, causing jitter peaking in the jitter transfer function. In
the AD805-VCXO circuit, the zero needed to stabilize the loop
is implemented in the feedback path, in the voltage-controlled
phase shifter. Placing the zero in the feedback path results in
fundamentally no jitter peaking since the zero is absent from the
closed-loop transfer function.
Output jitter, determined primarily by the VCXO, is a very low
0.6° rms. Jitter due to variations in input data density, pattern
jitter, is virtually eliminated in the circuit due to the AD805’s
patented phase detector.
The data retiming loop of the AD805 can be used with a passive
tuned circuit (155.52 MHz) such as a bandpass or a SAW filter
for clock recovery and data retiming. The data retiming loop
acts to servo the phase of the input data to the phase of the
recovered clock from the passive tuned circuit in this type of
application (see APPLICATIONS).
The AD805 uses 10 KH ECL levels and consumes 375 mW
from a +5 V or a –5.2 V supply. The device is specified for
operation over the industrial temperature range of –40°C to
+85°C and is available in a 20-pin plastic DIP.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
World Wide Web Site: http://www.analog.com
Fax: 617/326-8703
© Analog Devices, Inc., 1996
AD805–SPECIFICATIONS (V
EE
Parameter
Condition
NOMINAL DATA RATE
= VMIN to VMAX, TA = TMIN to TMAX ( unless otherwise noted)
Min
1
± 50
TRACKING RANGE/CAPTURE RANGE 1
AD805BN
Typ
Max
Units
155.52
Mbps
± 70
ppm of Nominal Data Rate
STATIC PHASE ERROR 1
27–1 PRN Sequence
223–1 PRN Sequence
7
7
33
33
Degrees
Degrees
OUTPUT JITTER1
27–1 PRN Sequence
223–1 PRN Sequence
0.6
0.6
1.0
1.0
Degrees rms
Degrees rms
JITTER TOLERANCE1
f = 10 Hz
f = 30 Hz
f = 300 Hz
f = 6.5 kHz
f = 65 kHz
f = 650 kHz
f = 1.3 MHz
OBS
JITTER TRANSFER1
Peaking
Bandwidth
RECOVERED CLOCK SKEW
TRANSITIONLESS DATA RUN
1
ACQUISITION TIME
VCXO CONTROL OUTPUT RESISTANCE
VCXO Control Voltage High Level (V CC – VOH)
VCXO Control Voltage Low Level (V OL – VEE)
POWER SUPPLY
Voltage (VMIN to VMAX)
Current
375
125
12.5
2.2
2.2
0.84
0.65
0
10
0.12
dB
kHz
OLE
TRCS
0.2
0.6
1.1
ns
1000
500
Bit Periods
27–1 PRN Sequence
30
44
Bit Periods
No Load
No Load
1000
1
0.8
1.3
1.15
Ω
Volts
Volts
–4.5
–5.2
70
–5.5
90
95
TA = +25°C
TE
Volts
mA
mA
–1.08
–1.95
–0.72
–1.59
Volts
Volts
–1.08
–1.95
–0.72
–1.60
Volts
Volts
125
80
µA
µA
1.5
1.5
ns
ns
OUTPUT VOLTAGE LEVELS
Output Logic High, VOH
Output Logic Low, V OL
TA = +25°C
INPUT CURRENT LEVELS
Input Logic High, IIH
Input Logic Low, IIL
TA = +25°C
OUTPUT SLEW TIMES
Rise Time (tR)
Fall Time (tF)
TA = +25°C
20%–80%
80%–20%
0.75
0.75
BUFFERED CLOCK DISTORTION
(DUTY CYCLE DISTORTION)
Recovered Clock Output
ρ = 1/2, TA = +25°C,
VEE = –5.2 V
± 0.5
OPERATING TEMPERATURE RANGE
(TMIN to TMAX)
Unit Intervals p-p
Unit Intervals p-p
Unit Intervals p-p
Unit Intervals p-p
Unit Intervals p-p
Unit Intervals p-p
Unit Intervals p-p
27–1 PRN Sequence
TA = +25°C, VEE = –5.2 V
INPUT VOLTAGE LEVELS
Input Logic High, V IH
Input Logic Low, VIL
440
147
16
3.2
3.0
1.4
0.85
%
1
–40
+85
°C
Max
Units
VCXO CIRCUIT SPECIFICATIONS
Parameter
Condition
Min
CENTER FREQUENCY
Typ
155.52
CONTROL VOLTAGE
–4
MHz
–1
Volts
VCXO TUNING RANGE
± 50
± 70
ppm of Center Frequency
MODULATION BANDWIDTH
100
500
kHz
TRANSFER FUNCTION
Positive, Monotonic
N/A
NOTES
1
These specifications reflect the performance of the circuit shown in Figure 12. VCXO circuit parameters critical to overall circuit performance are listed above.
2
This specification results from tests accurate to ± 0.1 dB, and from statistical analysis of the test results distribution. The AD805-VCXO circuit has no jitter peaking.
Reference the discussion in the THEORY OF OPERATION section.
Specifications subject to change without notice.
–2–
REV. 0
AD805
ABSOLUTE MAXIMUM RATINGS*
DATAOUT 50%
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –6 V
Input Voltage (Pin 19 or 20 to VEE) . . . . . . . . VEE to +300 mV
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Maximum Junction Temperature
Plastic DIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . 150°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature (Soldering 60 sec) . . . . . . . . . . . . . +300°C
*Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. This is a stress rating only; functional operation
of the device at these or any other conditions above those indicated in the
operational section of the specification is not implied. Exposure to an absolute
maximum rating condition for an extended period may adversely affect device
reliability.
OBS
PIN CONFIGURATION
DATAOUT
1
20
DATAIN
DATAOUT
2
19
DATAIN
VCC2
3
18
SUBST
CLKOUT
4
17
CLKIN
CLKOUT
5
AD805
16
CLKIN
SUBST
6
TOP VIEW
(Not to Scale)
15
VEE
VEE
7
14
VCC1
VCC1
8
13
AVCC
9
12
VCXO
CONTROL
ASUBST
10
11
NC
TRCS
Figure 1. Recovered Clock Skew (See Specifications Page)
PIN DESCRIPTIONS
Number Mnemonic
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Description
DATAOUT
DATAOUT
VCC2
CLKOUT
CLKOUT
SUBST
VEE
VCC1
AVEE
ASUBST
NC
VCXO CONTROL
AVCC
VCC1
VEE
CLKIN
CLKIN
SUBST
DATAIN
DATAIN
OLE
NOTES:
PIN 6 AND 18
ARE DIGITAL SUBSTRATE
AND SHOULD BE CONNECTED
TO PINS 7 AND 15 WHICH
ARE DIGITAL VEE .
PIN 10 IS ANALOG SUBSTRATE
AND SHOULD BE CONNECTED
TO PIN 9, WHICH IS ANALOG VEE.
AVEE
CLKOUT 50%
NC = NO CONNECT
Differential Retimed Data Output
Differential Retimed Data Output
Digital Ground
Differential Recovered Clock Output
Differential Recovered Clock Output
Substrate
Digital VEE
Digital Ground
Analog VEE
Analog Substrate
No Connection
VCXO Control Voltage Output
Analog Ground
Digital Ground
Digital VEE
Differential Clock Input
Differential Clock Input
Substrate
Differential Data Input
Differential Data Input
TE
ORDERING GUIDE AND THERMAL CHARACTERISTICS
Device
Description
Operating
Temperature
uJA
Package
Option
AD805BN
20-Pin Plastic DIP
–40°C to +85°C
80°C/W
N-20
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD805 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. 0
–3–
WARNING!
ESD SENSITIVE DEVICE
AD805
GLOSSARY
Jitter Tolerance
AD805 performance is specified using a Vectron C0-434Y ECL
Series Hybrid VCXO, SCD No. 434Y2365.
Jitter tolerance is a measure of the circuit’s ability to track a
jittery input data signal. Jitter on the input data is best thought
of as phase modulation and is usually specified in Unit Intervals
(UI). The circuit will have a bit error rate less than 1 × 10–10
when in lock and retiming input data that has the specified jitter
applied to it.
Nominal Data Rate
This is the data rate that the circuit is specified to operate on.
The data format is Nonreturn to Zero (NRZ).
Operating Temperature Range (T MIN to TMAX)
Refer to the THEORY OF OPERATION section for a description of the jitter tolerance of the AD805-VCXO circuit.
This is the operating temperature range of the AD805 in the
circuit. Each of the additional components of the circuit is held
at 25°C, nominal. The operating temperature range of the
circuit can be extended to the operating temperature range of
the AD805 through the selection of circuit components that
operate from TMIN to TMAX.
Jitter Transfer
The circuit exhibits a low-pass filter response to jitter applied to
its input data. The circuit jitter transfer characteristics are
measured using the method described in CCITT Recommendation G.958, Geneva 1990, Section 6.3.2. This method involves
applying sinusoidal input jitter up to the jitter tolerance mask
level for an STM-1 Type A regenerator.
OBS
Tracking Range
This is the range of input data rates over which the circuit will
remain in lock. The VCXO CONTROL voltage range and the
VCXO frequency range determine circuit tracking range.
Capture Range
Bandwidth
This describes the frequency at which the circuit attenuates
sinusoidal input jitter by 3 dB.
OLE
This is the range of frequencies over which the circuit can
acquire lock. The VCXO CONTROL voltage range and the
VCXO frequency range determine circuit capture range.
Static Phase Error
Peaking
This describes the maximum jitter gain of the circuit in dB.
Acquisition Time
TE
This is the steady-state phase difference, in degrees, between the
recovered clock sampling edge and the optimum sampling
instant, which is assumed to be halfway between the rising and
falling edges of a data bit. Gate delays between the signals that
define static phase error and IC input and output signals
prohibit direct measurement of static phase error.
This is the transient time, measured in bit periods, required for
the circuit to lock on input data from its free-running state.
Recovered Clock Skew, T RCS
Bit Error Rate vs. Signal-to-Noise Ratio
Buffered Clock Distortion
This is a measure of the duty cycle distortion at the AD805
CLKOUT signals relative to the duty cycle distortion at the
AD805 CLKIN signals.
This is the time difference, in ns, between the recovered clock
signal rising edge midpoint and midpoint of the rising or falling
edge of the output data signal. Refer to Figure 1.
The AD805 is intended to operate with standard ECL signal
levels at the data input. Although not recommended, smaller
input signals are tolerable. Figure 6 shows the bit error rate
performance versus input signal-to-noise ratio for input signal
amplitudes of full 900 mV ECL, and decreased amplitudes of
80 mV and 20 mV. Wideband amplitude noise is summed with
the data signals as shown in Figure 2. The full ECL, 80 mV,
and 20 mV input signals give virtually indistinguishable results.
Data Transition Density, r
This is a measure of the number of data transitions, from “0” to
“1” and from “1” to “0,” over many clock periods. ρ is the ratio
(0 ≤ ρ ≤ 1) of data transitions to clock periods.
Transitionless Data Run
The axes used for Figure 6 are scaled so that the theoretical Bit
Error Rate vs. Signal to Noise Ratio curve appears as a straight
line. The curve that fits the actual data points has a slope that
matches the slope of the theoretical curve for all but the higher
values of signal-to-noise ratio and lower values of bit error rate.
For high values of signal-to-noise ratio, the noise generator used
clips, and therefore is not true Gaussian. The extreme peaks of
the noise cause bit errors for high signal to noise ratios and low
bit error rates. The clipping of the noise waveform limits bit
errors in these cases.
This is measured by interrupting an input data pattern with
ρ = 1/2 with a block of data bits without transitions, and then
reapplying the ρ = 1/2 input data. The circuit will handle this
sequence without making a bit error. The length of the block of
input data without transitions that an AD805-VCXO circuit can
handle is a function of the VCXO K0. The VCXO in the circuit
of Figure 12 has a K0 of 60 radians/volt, nominally.
Jitter
This is the dynamic displacement of digital signals from their
long term average positions, measured in degrees rms, or Unit
Intervals (UI). Jitter on the input data can cause dynamic phase
errors on the recovered clock. Jitter on the recovered clock
causes jitter on the retimed data.
Output Jitter
This is the jitter on the retimed data, in degrees rms, due to a
specific pattern or some pseudo-random input data sequence
(PRN Sequence). The random output jitter of the VCXO
contributes to Output Jitter.
–4–
REV. 0
AD805
POWER
COMBINER
∑
+
DIFFERENTIAL
SIGNAL
SOURCE
DATAIN
0.47µF
100
50Ω
CIRCUIT
UNDER
TEST
50Ω
+
∑
–
JITTER TOLERANCE – UIp-p
+
0.47µF
DATAIN
POWER
COMBINER
75Ω
1.0µF
POWER
SPLITTER
180Ω
–5.2 V
GND
10
1
CCITT TYPE A MASK
FILTER
OBS
0.1
0.1
NOISE
SOURCE
1
Figure 2. Bit Error Rate vs. Signal-to-Noise Ratio Test:
Block Diagram
3E-2
2E-2
BIT ERROR RATE
JITTER GAIN – dB
–10
CCITT TYPE B
MASK
1.3 UI
INPUT
JITTER
–15
80mV
5E-3
3E-3
2E-3
3
5E-4
3E-4
2E-4
4
5
20mV
ECL
6
8
10
12
E-15
–20
1
10
100
JITTER FREQUENCY – kHz
8
1000
Figure 3. Jitter Transfer – Bandwidth
9
10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
S/N – dB
Figure 6. Bit Error Rate vs. Signal-to-Noise Ratio
0.3 UI
INPUT JITTER
VCXO CONTROL VOLTAGE – Volts
V CC
–1
JITTER GAIN – dB
TE
5E-2
E-2
TYPE A
MASK
INPUT
JITTER
1000
E-1
0.3 UI
INPUT JITTER
–5
100
Figure 5. Jitter Tolerance
OLE
0
1.3 UI
INPUT JITTER
–3
CCITT
TYPE A MASK
INPUT JITTER
–5
2.0
AD805
IOUT
V EE = –5.2V
1.5
VCC – VOH
1.0
0.5
VOL – VEE
0
1
JITTER FREQUENCY – kHz
10
–200
200
0
IOUT – mA
Figure 4. Jitter Transfer – Peaking
REV. 0
10
FREQUENCY – kHz
Figure 7. VCXO Control Voltage vs. Load
–5–
400
AD805
THEORY OF OPERATION
The AD805 is a delay- and phase- locked loop circuit for clock
recovery and data retiming from an NRZ-encoded data stream.
Figure 8 is a block diagram of the device shown with an external
VCXO. The AD805-VCXO circuit tracks the phase of the input
data using two feedback loops that share a common control
voltage. A high speed delay-locked loop path uses an on-chip
voltage-controlled phase shifter (VCPS) to track the high
frequency components of jitter on the input data. A separate
frequency control loop, using the external VCXO, tracks the low
frequency components of jitter on the input data.
peaking in any regenerative stage can contribute to hazardous
jitter accumulation.
ORDINARY PLL
JITTER OUT
(dB)
JITTER IN
Y(s)
X(s)
0 dB
Z(s)
1
DATA
INPUT
τ
AD805
VOLTAGE
CONTROLLED
PHASE
SHIFTER
INTERNAL LOOP
CONTROL VOLTAGE
OBS
LOOP
FILTER
PHASE
DETECTOR
RETIMING
MODULE
VCXO
(EXTERNAL)
RECOVERED
CLOCK
RETIMED
DATA
AD805 – VCXO
X(s)
sLOW
LOG ω
sHIGH
Figure 10. Circuit Jitter Transfer Functions
The error transfer function, e(s)/X(s), has the same high pass
form as an ordinary phase-locked loop. This transfer function is
free to be optimized to give excellent wide-band jitter accommodation since the jitter transfer function, Z(s)/X(s), provides the
narrow-band jitter filtering. The circuit has an error transfer
bandwidth of 3 MHz and a jitter transfer bandwidth of 10 kHz.
VCXO
CONTROL VOLTAGE
OLE
Figure 8. AD805-VCXO Clock Recovery Block Diagram
The circuit’s two loops contribute to overall jitter accommodation. At low frequencies, the integrator provides high gain so
that large jitter amplitudes can be tracked with small phase
errors between inputs of the phase detector. In this case, the
VCXO is frequency modulated and jitter is tracked as in an
ordinary phase-locked loop. The amount of low frequency jitter
that can be tracked is a function of the VCXO tuning range. A
wider tuning range corresponds to increased accommodation of
low frequency jitter. The internal loop control voltage remains
small for small phase errors, so the VCPS remains close to the
center of its range, contributing little to jitter accommodation.
The two loops work together to null out phase error. For
example, when the clock is behind the data, the phase detector
drives the VCXO to a higher frequency and also increases the
delay through the VCPS. These actions serve to reduce the
phase error. The faster clock picks up phase while the delayed
data loses phase. When considering a static phase error, it is
easy to see that since the control voltage is developed by a loop
integrator, the phase error will eventually reduce to zero.
TE
Another view of the circuit is that the AD805 VCPS implements
the zero that is required to stabilize a second order phase-locked
loop and that the zero is placed in the feedback path so it does
not appear in the closed-loop transfer function. Jitter peaking in
an ordinary second order phase-locked loop is caused by the
presence of this zero in the closed-loop transfer function. Since
the AD805-VCXO circuit is free of any zero in its closed-loop
transfer function, the circuit is free of jitter peaking.
At medium jitter frequencies, the gain and tuning range of the
VCXO are not enough to track input jitter. In this case the
VCXO control voltage input starts to hit the rails of its maximum voltage swing and the VCXO frequency output spends
most of the time at one or the other extreme of its tuning range.
The size of the VCXO tuning range therefore has a small effect
on the jitter accommodation. The AD805 internal loop control
voltage is now larger, so the VCPS takes on the burden of
tracking input jitter. The VCPS range (in UI) is seen as the
plateau on the jitter tolerance curve (Figure 11). The VCPS has
a minimum range of 2 UI.
A linearized block diagram of the AD805-VCXO circuit is
shown in Figure 9. The two loops simultaneously provide wideband jitter accommodation and narrow-band jitter filtering.
Y
τ
100
e
PHASE
SHIFTER
+
–
∑
+
∑
K
–
1
s
INT
1
s
VCO
Z
JITTER TOLERANCE – UIp-p
X
PHASE
DETECTOR
Z(s)
1
=
X(s)
s2
+ τs + 1
K
e(s)
s2
=
X(s)
s2+ Kτs + K
Figure 9. AD805-VCXO Circuit Linearized Block Diagram
10
AD805-VCXO
JITTER TOLERANCE
1
CCITT TYPE A MASK
The jitter transfer function, Z(s)/X(s), is second order and low
pass, providing excellent filtering. Note that the jitter transfer
function has no zero, unlike ordinary second-order phase-locked
loops. This means that the circuit has fundamentally no jitter
peaking (see Figure 10). Having no jitter peaking makes this
circuit ideal for signal regeneration applications where jitter
0.1
0.1
1
10
100
FREQUENCY – kHz
1000
10000
Figure 11. Jitter Accommodation Design Limit
–6–
REV. 0
AD805
The gain of the loop integrator is small for high jitter frequencies, so that larger phase differences between the phase detector
inputs are needed to make the internal loop control voltage big
enough to tune the range of the VCPS. Large phase errors at
high jitter frequencies cannot be tolerated. In this region, the
gain of the loop integrator determines the jitter accommodation.
Since the gain of the loop integrator declines linearly with
frequency, jitter accommodation decreases with increasing jitter
frequency. At the highest frequencies, the loop gain is very small
and little tuning of the VCPS can be expected. In this case, jitter
accommodation is determined by the eye opening of the input
data, the static phase error and the residual loop jitter. The jitter
accommodation is roughly 0.5 UI in this region. The corner
frequency between the declining slope and the flat region is the
3 MHz closed-loop bandwidth of the AD805’s internal
delay-locked loop.
OBS
USING THE AD805
Ground Planes
The AD805 design can be used with any VCXO circuit that has
a gain of roughly 1 3 106 rad/volt-sec, a frequency pull range of
at least ± 50 ppm, a positive slope (a greater VCXO control
voltage corresponds to a greater output frequency) and a
modulation bandwidth of 500 kHz. These VCXO parameters
contribute to overall circuit low frequency jitter tolerance and
jitter transfer.
The output jitter of the overall circuit is largely determined by
the output jitter of the VCXO. The AD805 adds little jitter
since it just buffers the VCXO frequency output, adding
distortion (duty cycle distortion) of only ± 0.5%.
Overall circuit jitter bandwidth is determined by the slope of the
VCXO output frequency vs. control voltage curve. A greater
slope corresponds to a greater jitter bandwidth.
OLE
Use of two ground planes, an analog ground plane and a digital
ground plane, is recommended. This will isolate noise that may
be on the digital ground plane from the analog ground plane.
Power Supply Connections
APPLICATIONS
155.52 MBPS CLOCK RECOVERY AND DATA RETIMING
USING AT&T 157-TYPE VHF VOLTAGE-CONTROLLED
CRYSTAL OSCILLATOR
Power supply decoupling should take place as close to the IC as
possible. This will keep noise that may be on a power supply
from affecting circuit performance.
Use of a 10 µF tantalum capacitor between VEE and ground is
recommended.
Use of 0.1 µF ceramic capacitors between IC power supply or
substrate pins and either analog or digital ground is recommended. Refer to schematic, Figure 12, for advised connections.
The ceramic capacitors should be placed as close to the IC pins
as possible.
Connections from VEE to load resistors for DATAIN, DATAOUT,
CLKIN, and CLKOUT signals should be individual, not daisy
chained. This will avoid crosstalk on these signals.
Transmission Lines
Use of 50 Ω transmission lines are recommended for DATAIN,
DATAOUT, CLKIN, and CLKOUT signals.
Figure 12 shows a schematic of the AD805 in a 155.52 Mbps
clock recovery and data retiming application with an AT&T
157-Type VCXO (see insert). Figures 15 and 16 show typical
jitter tolerance and jitter transfer curves for the circuit.
TE
Note that the 157-Type VCXO control voltage bandwidth
(modulation bandwidth) varies with respect to control voltage
from 80 kHz to 500 kHz. The low value of this modulation
bandwidth causes some jitter peaking when used with the
AD805. The limited modulation bandwidth introduces excess
phase in the frequency control loop through the VCXO. This
causes the frequency control loop to become less damped. Jitter
peaking of 1 dB or 2 dB results in the jitter transfer function.
The compensation network on the VCXO control voltage
between the AD805 and the 157-Type VCXO shown in Figure
12, effectively reduces the high frequency loop gain through the
frequency control loop. The addition of this compensation
network eliminates jitter peaking. The compensation network
1 kΩ resistor works with the AD805 VCXO CONTROL 1 kΩ
output impedance to halve the loop crossover frequency. This
avoids excess phase caused by the limited modulation bandwidth of the 157-Type VCXO.
Terminations
Termination resistors should be used for DATAIN, CLKIN,
DATAOUT, and CLKOUT signals. Metal, thick film, 1%
tolerance resistors are recommended. Termination resistors for
the DATAIN and CLKIN signals should be placed as close as
possible to the DATAIN and CLKIN pins.
Input Buffer
Use of an input buffer, such as a 10H116 Line Receiver IC, is
suggested for an application where the DATAIN signals do not
come directly from an ECL gate, or where noise immunity on
the DATAIN signals is an issue.
REV. 0
–7–
AD805
–5.2V
C9
0.1µF
R15
130Ω
R13
80.6Ω
–5.2V
R16
130Ω
R14
80.6Ω
–5.2V
1
16
2
15
14
3
Z2
4
J1
DATAOUT
R1
100Ω
R2
100Ω
R10
154Ω
R5 100Ω
R9
154Ω
J2
DATAOUT
R6
100Ω
–5.2V
J3
C4
0.1µF
C3
0.1µF
DATAIN 20
2 DATAOUT
DATAIN 19
R11
154Ω
J4
R7 100Ω
R8 100Ω
R3
100Ω
–5.2V
–5.2V
C2
10µF
8 VCC1
AVCC 13
9 AVEE
VCXO
CONTROL 12
11
7
10
8
9
Z1
0.1µF
ANALOG
GROUND
J5
DATAIN
DATAIN
–5.2V
R17
80.6Ω
C12
0.1µF
C8
–5.2V
0.1µF
R23
80.6Ω
R22
130Ω
R18
80.6Ω
R21
130Ω
16
9
10
R24
80.6Ω
NC 11
AD805
VECTRON
CO-434V VCXO
20mh
1nF
OPTIONAL
NOTCH
FILTER*
C16
0.1µF
A B C
A
–5.2V
C13
0.1µF
C1
1.0µF
NC = NO CONNECT
* A NOTCH FILTER MAY BE USED TO
FILTER A VCXO CIRCUIT'S SPURIOUS
RESPONSE EFFECTIVELY.
–5.2V
8
6
R25
1kΩ
DIGITAL
GROUND
R20
130Ω
C10
OLE
10 ASUBST
C6
0.1µF
6
R19
130Ω
–5.2V
VCC1 14
7 VEE
C5
0.1µF
–5.2V
VEE 15
6 SUBST
R4
100Ω
12
CLKIN 16
5 CLKOUT
CLOCKOUT
5
J6
CLKIN 17
4 CLKOUT
R12
154Ω
C7
0.1µF
SUBST 18
3 VCC2
OBS
CLOCKOUT
13
10H116
1 DATAOUT
C11
0.1µF
C
B
TE
16
1
15
2
3
4
Z3
AT&T
157-TYPE
VCXO
14
13
5
12
6
11
7
10
8
9
157
AT&T TYPE VCXO CIRCUIT
Figure 12. Evaluation Board Schematic, Negative Supply
Figure 13. Evaluation Board, Component Side
Figure 14. Evaluation Board, Solder Side
–8–
REV. 0
AD805
Table I. Evaluation Board,
Negative Supply: Components List
Reference
Designator
R1–8
R9–12
R13, 14, 17, 18, 23, 24
R15, 16, 19–22
C2
C3–12, C15
Z1
Z2
Description
Quantity
Resistor, 100 Ω, 1%
Resistor, 154 Ω, 1%
Resistor, 80.6 Ω, 1%
Resistor, 130 Ω, 1%
10 µF, Tantalum
0.1 µF, Ceramic Chip
AD805
10H116, ECL Line Receiver
Vectron CO-434Y VCXO
AT&T 157-Type VCXO
8
4
6
6
1
11
1
1
1
1
OBS
Z3
100
JITTER TOLERANCE – UIp-p
155.52 MBPS CLOCK RECOVERY AND DATA RETIMING
USING A SURFACE ACOUSTIC WAVE (SAW) FILTER
The jitter bandwidth and the output jitter of the overall circuit is
determined largely by the SAW filter used. The AD805 retimes
the input data to the recovered clock and buffers the recovered
clock from the SAW filter circuit. The AD805 plays a role in the
jitter accommodation of the overall circuit. The AD805’s phase
shifter range and the bandwidth of the data retiming loop
provide for at least 2 UI p-p jitter tolerance to 1 MHz. The
length of a transitionless block of data that will not cause the
circuit to lose lock or start making bit errors is determined by
the Q of the SAW filter used.
OLE
10
VECTRON
AT&T
1
1
10
100
JITTER FREQUENCY – kHz
TE
Figure 17 shows a schematic of the AD805 used with a
Toyocom TQS-610J-6R SAW filter. The circuit that precedes
the SAW filter feeds the filter with a pulse at each data transition. The line receiver circuit that immediately follows the SAW
filter provides gain to the SAW filter output to drive the AD805
CLKIN signals.
CCITT TYPE A MASK
0.1
0.1
The AD805 can be used with a 155.52 MHz SAW filter circuit
for clock recovery and data retiming. In this type of application
(refer to Figure 17), the SAW filter circuit is used to generate a
155.52 MHz clock from the input data. The AD805 data retiming
loop formed by the voltage-controlled phase shifter, the phase
detector and the loop filter, act to servo the phase of the input
data to the phase of the recovered clock. The AD805 can
compensate up to ± 180° phase variance through the SAW filter
circuit. The AD805 replaces the D Flip-Flop and phase shifter
components found in traditional SAW filter-based clock recovery
and data retiming circuits. Use of the AD805 eliminates the
phase shifter to SAW filter matching needed to get traditional
SAW filter-based circuits to perform over operating conditions.
1000
Figure 15. AD805-VCXO Circuit Jitter Tolerance
0
JITTER GAIN – dB
–5
AT&T 1.3 UI
INPUT JITTER
–10
VECTRON 1.3 UI
INPUT JITTER
CCITT TYPE B
MASK
–15
–20
1
10
100
JITTER FREQUENCY – kHz
1000
Figure 16. AD805-VCXO Circuit Jitter Transfer
REV. 0
–9–
AD805
–5.2V
C9
0.1µF
R15
130Ω
R13
80.6Ω
–5.2V
R16
130Ω
R14
80.6Ω
1
16
2
15
Z2
4
J1
DATAOUT
R1
100Ω
R2
100Ω
R10
154Ω
R5 100Ω
R9
154Ω
1 DATAOUT
R6
100Ω
–5.2V
C7
0.1µF
C4
0.1µF
R7 100Ω
R11
154Ω
R12
154Ω
R4
100Ω
R8 100Ω
R3
100Ω
C5
0.1Ω
4 CLKOUT
CLKIN 17
5 CLKOUT
CLKIN 16
VCC1 14
8 V CC1
AV CC 13
OBS
C2
10µF
C8
10
8
9
J5
DATAIN
DATAIN
C12
0.1µF
R34
130Ω
R17
80.6Ω
R18
80.6Ω
R35
130Ω
R 80.6Ω
R32
80.6Ω
NC 11
Z1
R33
80.6Ω
AD805
8
ANALOG
GROUND
NC = NO CONNECT
11
7
J6
–5.2V
0.1µF
3
2
1/3 Z3
16
C21
0.47µF
R30
10kΩ
R28
10kΩ
C20
0.47µF
OLE
C10
0.1µF
DIGITAL
GROUND
12
6
VCXO
CONTROL 12
10 ASUBST
C6
0.1µF
5
R20
130Ω
–5.2V
V EE 15
7 V EE
9 AVEE
–5.2V
–5.2V
R19
130Ω
–5.2V
SUBST 18
6 SUBST
CLOCKOUT
C10
0.1µF
DATAIN 19
3 V CC2
CLOCKOUT
J4
DATAIN 20
2 DATAOUT
J3
C11
0.1µF
13
10H116
C3
0.1µF
J2
DATAOUT
–5.2V
14
3
R31
10kΩ
1/3 Z3
C19
0.47µF
R29
10kΩ
1/3 Z3 10H116
5
7
10
15
13
4
6
9
14
12
C14
1nF
R27
274Ω
–5.2V
R25
274Ω
R26
274Ω
C17
0.1µF
–5.2V
TOYOCOM
TQS-610J-6R
R21
226Ω
TE
C15
1nF
1
R22
590Ω
R23
590Ω
R24
274Ω
C16
0.1µF
L1
1µh
T50-10 CORE,
18 TURNS
–5.2V
C13
0.1µF
Figure 17. AD805-SAW Filter Clock Recovery and Data Retiming Circuit Schematic
Table II. AD805-SAW Filter Clock Recovery and Data Retiming Components List
Reference
Designator
R1–R8
R9–R12
R13, R14, R17, R18, R32, R33
R15, R16, R19, R20, R34, R35
R21
R22, R23
R24–R27
R28–R31
C2
C3–C13, C16–C18
C14, C15
C19–C21
L1
Z1
Z2, Z3
Z4
Description
Quantity
Resistor, 100 Ω, 1%
Resistor, 154 Ω, 1%
Resistor, 80.6 Ω, 1%
Resistor, 130 Ω, 1%
Resistor, 226 Ω, 1%
Resistor, 590 Ω, 1%
Resistor, 274 Ω, 1%
Resistor, 10 kΩ, 1%
10 µF, Tantalum
0.1 µF, Ceramic Chip
1 nF
0.47 mF
1 µh, T50-10 Core, 18 Turns,
Micrometals, Inc.
AD805
1OH116, ECL Line Receiver
Toyocom TQS-610J-6R SAW
8
4
6
6
1
2
4
4
1
14
2
3
1
–10–
1
2
1
REV. 0
AD805
LARGE FACTOR FREQUENCY MULTIPLICATION —
TO 155.52 MHZ
DESKEWING ISOCHRONOUS 155.52 MBPS DATA
STREAMS
The AD805-VCXO combination can be used to multiply a
frequency at the AD805’s DATAIN by a large integer multiple.
This is useful for generating a 155.52 MHz bit clock from a
19.44 MHz byte clock (multiplication factor of 8). The highly
accurate center frequency of the VCXO makes even larger
factor frequency multiplication possible. The VCXO will not
lock on a false harmonic even for large multiplication factors.
For example, a VCXO with center frequency accuracy of
100 ppm will allow frequency multiplication by a factor as large
as 5000. This is because the 5000th harmonic of 31.104 kHz is
155.52 MHz, and the 4999th and the 5001st harmonics are 200
ppm away from the VCXO center frequency. Since the accuracy
and tuning range of the VCXO constrain its output frequency to
within 100 ppm of center frequency, the circuit will reliably pick
the 5000th harmonic.
The AD805 can be used for deskewing a 155.52 Mbps data
stream to a reference 155.52 MHz clock when the clock is
isochronous with the data. Figure 19 shows a diagram of an
AD805 in a deskewing application. The data input to the
AD802-155 clock recovery circuit and the data input to the
AD805 were generated using the same 155.52 MHz clock. The
AD805 data retiming loop formed by the voltage-controlled
phase shifter, the phase detector, and the loop filter act to align
the phase of the input data to the phase of the recovered clock.
This eliminates skew that can exist between two isochronous
data paths.
OBS
Frequency multiplication by an odd factor is possible using the
AD805-VCXO combination. This is not obvious. Consider a
51.84 MHz input multiplied by a factor of 3 to get to 155.52 MHz.
In this case, the edge spacing of the 51.84 MHz signal is 9.65 ns,
or 1-1/2 periods of the expected 155.52 MHz output. In theory,
every other edge of the 51.84 MHz at the AD805’s DATAIN is
interpreted as 180° out of phase. In practice, however, the
inherent loop jitter dithers these edges to give +179° then –179°
out of phase measurements on alternate edges. Measurements
on these alternate edges cancel. The circuit phase locks to the
other set of alternate edges. The very low gain of the VCXO and
the narrow bandwidth of the jitter transfer function gives an
output that has low jitter even though alternate input edges are
out of phase. When multiplying by a factor of 3, the DATAOUT
will have a repeating 110 or 100 pattern. Either pattern can
occur since either the rising or falling edges of the 51.84 MHz
signal at the DATAIN can be the out of phase set of alternate
edges.
The AD805 will track ± 180° change in skew after initial locking
without bit errors. If the skew changes by more than ± 180° after
lock, it is possible to exceed the range of the voltage controlled
phase shifter. Exceeding the phase shifter range will force the
AD805 data retiming loop to reacquire to the center of the
phase shifter. During this reacquisition, it is possible to make
3000 bit errors.
OLE
REFERENCE
DATA INPUT
PHASE
DETECTOR
CD
TE
COMPENSATING
ZERO
FREQUENCY
DETECTOR
∑
LOOP
FILTER
VCO
RECOVERED
CLOCK
RETIMING
MODULE
FRAC
OUTPUT
AD802-155
Figure 18 shows the output jitter performance of an AD805VCXO circuit for different integer frequency multiplication
factors.
DATA
INPUT
RETIMED
DATA
VOLTAGE
CONTROLLED
PHASE
SHIFTER
PHASE
DETECTOR
LOOP
FILTER
GAIN
VCXO
CONTROL
OUTPUT
RETIMING
MODULE
60
BUFFERED
CLOCK
OUTPUT JITTER – ps rms
50
AD805
Figure 19. AD805 Deskewing Circuit Diagram
40
30
20
10
0
10
INPUT CLOCK FREQUENCY – MHz
100
Figure 19. AD805-VCXO Circuit Clock Output Jitter vs.
Integer Multiplier
REV. 0
RETIMED
DATA
–11–
AD805
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
20-Pin Plastic Dual In-Line Package
(N-20)
20
11
1
10
PIN 1
0.280 (7.11)
0.240 (6.10)
0.060 (1.52)
0.015 (0.38)
0.210 (5.33)
MAX
0.130
(3.30)
MIN
0.160 (4.06)
0.115 (2.93)
OBS
0.022 (0.558)
0.014 (0.356)
0.100
(2.54)
BSC
0.070 (1.77) SEATING
0.045 (1.15) PLANE
C1777–10–4/93
1.060 (26.90)
0.925 (23.50)
0.325 (8.25)
0.300 (7.62) 0.195 (4.95)
0.115 (2.93)
0.015 (0.381)
0.008 (0.204)
OLE
PRINTED IN U.S.A.
TE
–12–
REV. 0