AD ADN2804ACPZ-RL7

622 Mbps Clock and Data Recovery IC
with Integrated Limiting Amplifier
ADN2804
FEATURES
GENERAL DESCRIPTION
Exceeds SONET requirements for jitter transfer/
generation/tolerance
Quantizer sensitivity: 3.3 mV typical
Adjustable slice level: ±95 mV
Patented clock recovery architecture
Loss-of-signal (LOS) detect range: 2.6 mV to 18.4 mV
Independent slice level adjust and LOS detector
No reference clock required
Loss-of-lock indicator
I2C® interface to access optional features
Single-supply operation: 3.3 V
Low power: 423 mW typical
5 mm × 5 mm, 32-lead LFCSP, Pb free
The ADN2804 provides the receiver functions of quantization,
signal level detect, clock and data recovery, and data retiming
for 622 Mbps NRZ data. The ADN2804 automatically locks to
622 Mbps data without the need for an external reference clock
or programming. In the absence of input data, the output clock
drifts no more than ±5%. All SONET jitter requirements are
met, including jitter transfer, jitter generation, and jitter
tolerance. All specifications are quoted for −40°C to +85°C
ambient temperature, unless otherwise noted.
This device, together with a PIN diode and a TIA preamplifier,
can implement a highly integrated, low cost, low power fiber
optic receiver.
The receiver’s front-end loss-of-signal (LOS) detector circuit
indicates when the input signal level falls below a user-adjustable
threshold. The LOS detect circuit has hysteresis to prevent chatter
at the output.
APPLICATIONS
BPON ONT
SONET OC-12
WDM transponders
Regenerators/repeaters
Test equipment
Broadband cross-connects and routers
The ADN2804 is available in a compact 5 mm × 5 mm,
32-lead LFCSP.
FUNCTIONAL BLOCK DIAGRAM
REFCLKP/REFCLKN
(OPTIONAL)
SLICEP/SLICEN
2
LOL
CF1
CF2
FREQUENCY
DETECT
LOOP
FILTER
PHASE
DETECT
LOOP
FILTER
VCC
VEE
PIN
NIN
QUANTIZER
PHASE
SHIFTER
VCO
VREF
DATA
RE-TIMING
2
2
THRADJ
LOS
DATAOUTP/
DATAOUTN
CLKOUTP/
CLKOUTN
ADN2804
05801-001
LOS
DETECT
Figure 1.
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 that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2006 Analog Devices, Inc. All rights reserved.
ADN2804
TABLE OF CONTENTS
Features .............................................................................................. 1
Jitter Specifications......................................................................... 13
Applications....................................................................................... 1
Theory of Operation ...................................................................... 14
General Description ......................................................................... 1
Functional Description.................................................................. 16
Functional Block Diagram .............................................................. 1
Frequency Acquisition............................................................... 16
Revision History ............................................................................... 2
Limiting Amplifier ..................................................................... 16
Specifications..................................................................................... 3
Slice Adjust.................................................................................. 16
Jitter Specifications....................................................................... 4
Loss-of-Signal (LOS) Detector ................................................. 16
Output and Timing Specifications ............................................. 5
Lock Detector Operation .......................................................... 17
Absolute Maximum Ratings............................................................ 6
SQUELCH Modes ...................................................................... 17
Thermal Characteristics .............................................................. 6
I2C Interface ................................................................................ 17
ESD Caution.................................................................................. 6
Reference Clock (Optional) ...................................................... 19
Timing Characteristics..................................................................... 7
Applications Information .............................................................. 21
Pin Configuration and Function Descriptions............................. 8
PCB Design Guidelines ............................................................. 21
Typical Performance Characteristics ............................................. 9
DC-Coupled Application .......................................................... 23
I2C Interface Timing and Internal Register Description........... 10
Outline Dimensions ....................................................................... 24
Terminology .................................................................................... 12
Ordering Guide .......................................................................... 24
REVISION HISTORY
2/06—Revision 0: Initial Version
Rev. 0 | Page 2 of 24
ADN2804
SPECIFICATIONS
TA = TMIN to TMAX, VCC = VMIN to VMAX, VEE = 0 V, CF = 0.47 μF, SLICEP = SLICEN = VEE, input data pattern: PRBS 223 − 1,
unless otherwise noted.
Table 1.
Parameter
QUANTIZER—DC CHARACTERISTICS
Input Voltage Range
Peak-to-Peak Differential Input
Input Common-Mode Level
Differential Input Sensitivity
Input Offset
Input RMS Noise
QUANTIZER—AC CHARACTERISTICS
Data Rate
Output Clock Range
S11
Input Resistance
Input Capacitance
QUANTIZER—SLICE ADJUSTMENT
Gain
Differential Control Voltage Input
Control Voltage Range
Slice Threshold Offset
LOSS-OF-SIGNAL (LOS) DETECT
Loss-of-Signal Detect Range (see Figure 6)
Hysteresis (Electrical)
LOS Assert Time
LOS Deassert Time
LOSS-OF-LOCK (LOL) DETECT
VCO Frequency Error for LOL Assert
VCO Frequency Error for LOL Deassert
LOL Response Time
ACQUISITION TIME
Lock to Data Mode
Optional Lock to REFCLK Mode
DATA RATE READBACK ACCURACY
Fine Readback
POWER SUPPLY VOLTAGE
POWER SUPPLY CURRENT
OPERATING TEMPERATURE RANGE
1
2
Conditions
Min
@ PIN or NIN, dc-coupled
PIN − NIN
DC-coupled (see Figure 27, Figure 28, and Figure 29)
223 − 1 PRBS, ac-coupled, 1 BER = 1 × 10–10
1.8
2.3
6
BER = 1 × 10–10
2.5
3.3
500
290
Max
Unit
2.8
2.0
2.8
V
V
V
mV p-p
μV
μV rms
622
622 ± 5%
−15
100
0.65
Absence of input data
@ 622 MHz
Differential
SLICEP − SLICEN = ±0.5 V
SLICEP − SLICEN
DC level @ SLICEP or SLICEN
Typ
0.10
−0.95
VEE
0.11
Mbps
MHz
dB
Ω
pF
0.13
+0.95
0.95
V/V
V
V
mV
1
RTHRESH = 0 Ω
RTHRESH = 100 kΩ
OC-12
RTHRESH = 0 Ω
RTHRESH = 100 kΩ
DC-coupled 2
DC-coupled2
14.9
2.6
16.7
3.5
18.4
4.4
mV
mV
6.2
4.1
6.9
6.1
500
400
7.7
8.1
dB
dB
ns
ns
With respect to nominal
With respect to nominal
OC-12
1000
250
200
ppm
ppm
μs
OC-12
2.0
20.0
ms
ms
In addition to REFCLK accuracy
OC-12
3.0
Locked to 622.08 Mbps
–40
100
3.3
128
3.6
+85
ppm
V
mA
°C
PIN and NIN should be differentially driven and ac-coupled for optimum sensitivity.
When ac-coupled, the LOS assert and deassert times are dominated by the RC time constant of the ac coupling capacitor and the 50 Ω input termination of the
ADN2804 input stage.
Rev. 0 | Page 3 of 24
ADN2804
JITTER SPECIFICATIONS
TA = TMIN to TMAX, VCC = VMIN to VMAX, VEE = 0 V, CF = 0.47 μF, SLICEP = SLICEN = VEE, input data pattern: PRBS 223 − 1,
unless otherwise noted.
Table 2.
Parameter
PHASE-LOCKED LOOP CHARACTERISTICS
Jitter Transfer Bandwidth
Jitter Peaking
Jitter Generation
Jitter Tolerance
1
Conditions
Min
OC-12
OC-12
OC-12, 12 kHz to 5 MHz
OC-12, 223 − 1 PRBS
30 Hz 1
300 Hz1
25 kHz
250 kHz1
100
44
2.5
1.0
Jitter tolerance of the ADN2804 at these jitter frequencies is better than what the test equipment is able to measure.
Rev. 0 | Page 4 of 24
Typ
Max
Unit
75
0
0.001
0.011
130
0.03
0.003
0.026
kHz
dB
UI rms
UI p-p
UI p-p
UI p-p
UI p-p
UI p-p
ADN2804
OUTPUT AND TIMING SPECIFICATIONS
Table 3.
Parameter
LVDS OUTPUT CHARACTERISTICS
(CLKOUTP/CLKOUTN, DATAOUTP/DATAOUTN)
Output Voltage High
Output Voltage Low
Differential Output Swing
Output Offset Voltage
Output Impedance
LVDS Outputs’ Timing
Rise Time
Fall Time
Setup Time
Hold Time
I2C INTERFACE DC CHARACTERISTICS
Input High Voltage
Input Low Voltage
Input Current
Output Low Voltage
I2C INTERFACE TIMING
SCK Clock Frequency
SCK Pulse Width High
SCK Pulse Width Low
Start Condition Hold Time
Start Condition Setup Time
Data Setup Time
Data Hold Time
SCK/SDA Rise/Fall Time
Stop Condition Setup Time
Bus Free Time Between a Stop and a Start
REFCLK CHARACTERISTICS
Input Voltage Range
Minimum Differential Input Drive
Reference Frequency
Required Accuracy
LVTTL DC INPUT CHARACTERISTICS
Input High Voltage
Input Low Voltage
Input High Current
Input Low Current
LVTTL DC OUTPUT CHARACTERISTICS
Output High Voltage
Output Low Voltage
1
Conditions
Min
VOH (see Figure 3)
VOL (see Figure 3)
VOD (see Figure 3)
VOS (see Figure 3)
Differential
925
250
1125
20% to 80%
80% to 20%
TS (see Figure 2), OC-12
TH (see Figure 2), OC-12
LVCMOS
VIH
VIL
VIN = 0.1 VCC or VIN = 0.9 VCC
VOL, IOL = 3.0 mA
See Figure 11
760
760
Typ
Max
Unit
1475
mV
mV
mV
mV
Ω
320
1200
100
400
1275
115
115
800
800
220
220
840
840
ps
ps
ps
ps
0.3 VCC
+10.0
0.4
V
V
μA
V
0.7 VCC
−10.0
400
tHIGH
tLOW
tHD;STA
tSU;STA
tSU;DAT
tHD;DAT
TR/TF
tSU;STO
tBUF
Optional lock to REFCLK mode
@ REFCLKP or REFCLKN
VIL
VIH
600
1300
600
600
100
300
20 + 0.1 Cb 1
600
1300
300
0
VCC
100
10
160
100
VIH
VIL
IIH, VIN = 2.4 V
IIL, VIN = 0.4 V
2.0
VOH, IOH = −2.0 mA
VOL, IOL = +2.0 mA
2.4
Cb = total capacitance of one bus line in picofarads. If used with Hs-mode devices, faster fall times are allowed.
Rev. 0 | Page 5 of 24
0.8
5
−5
0.4
kHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
V
V
mV p-p
MHz
ppm
V
V
μA
μA
V
V
ADN2804
ABSOLUTE MAXIMUM RATINGS
TA = TMIN to TMAX, VCC = VMIN to VMAX, VEE = 0 V, CF =
0.47 μF, SLICEP = SLICEN = VEE, unless otherwise noted.
Table 4.
Parameter
Supply Voltage (VCC)
Minimum Input Voltage (All Inputs)
Maximum Input Voltage (All Inputs)
Maximum Junction Temperature
Storage Temperature Range
Rating
4.2 V
VEE − 0.4 V
VCC + 0.4 V
125°C
−65°C to +150°C
Stress 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 sections of
this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
THERMAL CHARACTERISTICS
Thermal Resistance
32-lead LFCSP, 4-layer board with exposed paddle soldered to
VEE, θJA = 28°C/W.
ESD 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 this product 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 | Page 6 of 24
ADN2804
TIMING CHARACTERISTICS
CLKOUTP
TH
05801-002
TS
DATAOUTP/
DATAOUTN
Figure 2. Output Timing
DIFFERENTIAL CLKOUTP/N, DATAOUTP/N
VOH
VOS
05801-032
|VOD|
VOL
Figure 3. Differential Output Specifications
5mA
RLOAD
100Ω
100Ω
VDIFF
SIMPLIFIED LVDS
OUTPUT STAGE
Figure 4. Differential Output Stage
Rev. 0 | Page 7 of 24
05801-033
5mA
ADN2804
32 TEST2
31 VCC
30 VEE
29 DATAOUTP
28 DATAOUTN
27 SQUELCH
26 CLKOUTP
25 CLKOUTN
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
ADN2804*
TOP VIEW
(Not to Scale)
24 VCC
23 VEE
22 LOS
21 SDA
20 SCK
19 SADDR5
18 VCC
17 VEE
* THERE IS AN EXPOSED PAD ON THE BOTTOM OF
THE PACKAGE THAT MUST BE CONNECTED TO GND.
05801-004
PIN 1
INDIC ATOR
THRADJ 9
REFCLKP 10
REFCLKN 11
VCC 12
VEE 13
CF2 14
CF1 15
LOL 16
TEST1 1
VCC 2
VREF 3
NIN 4
PIN 5
SLICEP 6
SLICEN 7
VEE 8
Figure 5. Pin Configuration
Table 5. Pin Function Descriptions
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
Exposed Pad
1
Mnemonic
TEST1
VCC
VREF
NIN
PIN
SLICEP
SLICEN
VEE
THRADJ
REFCLKP
REFCLKN
VCC
VEE
CF2
CF1
LOL
VEE
VCC
SADDR5
SCK
SDA
LOS
VEE
VCC
CLKOUTN
CLKOUTP
SQUELCH
DATAOUTN
DATAOUTP
VEE
VCC
TEST2
Pad
Type 1
P
AO
AI
AI
AI
AI
P
AI
DI
DI
P
P
AO
AO
DO
P
P
DI
DI
DI
DO
P
P
DO
DO
DI
DO
DO
P
P
P
Description
Connect to VCC.
Power for Limiting Amplifier, LOS.
Internal VREF Voltage. Decouple to GND with a 0.1 μF capacitor.
Differential Data Input. CML.
Differential Data Input. CML.
Differential Slice Level Adjust Input.
Differential Slice Level Adjust Input.
GND for Limiting Amplifier, LOS.
LOS Threshold Setting Resistor.
Differential REFCLK Input. 10 MHz to 160 MHz.
Differential REFCLK Input. 10 MHz to 160 MHz.
VCO Power.
VCO GND.
Frequency Loop Capacitor.
Frequency Loop Capacitor.
Loss-of-Lock Indicator. LVTTL active high.
FLL Detector GND.
FLL Detector Power.
Slave Address Bit 5.
I2C Clock Input.
I2C Data Input.
Loss-of-Signal Detect Output. Active high. LVTTL.
Output Buffer, I2C GND.
Output Buffer, I2C Power.
Differential Recovered Clock Output. LVDS.
Differential Recovered Clock Output. LVDS.
Disable Clock and Data Outputs. Active high. LVTTL.
Differential Recovered Data Output. LVDS.
Differential Recovered Data Output. LVDS.
Phase Detector, Phase Shifter GND.
Phase Detector, Phase Shifter Power.
Connect to VCC.
Connect to GND.
Type: P = power, AI = analog input, AO = analog output, DI = digital input, DO = digital output.
Rev. 0 | Page 8 of 24
ADN2804
TYPICAL PERFORMANCE CHARACTERISTICS
16
12
10
8
6
4
2
1
10
100
1k
10k
Figure 6. LOS Comparator Trip Point Programming
Rev. 0 | Page 9 of 24
100k
05801-005
TRIP POINT (mV p-p)
14
ADN2804
I2C INTERFACE TIMING AND INTERNAL REGISTER DESCRIPTION
1
A5
MSB = 1
SET BY
PIN 19
0
0
0
0
0
X
0 = WR
1 = RD
05801-007
R/W
CTRL.
SLAVE ADDRESS [6...0]
S
SLAVE ADDR, LSB = 0 (WR) A(S) SUB ADDR A(S) DATA A(S)
DATA A(S)
P
05801-008
Figure 7. Slave Address Configuration
2
Figure 8. I C Write Data Transfer
SLAVE ADDR, LSB = 0 (WR) A(S) SUB ADDR
A(S) S SLAVE ADDR, LSB = 1 (RD) A(S) DATA
A(M)
DATA A(M) P
P = STOP BIT
A(M) = LACK OF ACKNOWLEDGE BY MASTER
A(M) = ACKNOWLEDGE BY MASTER
05801-009
S
S = START BIT
A(S) = ACKNOWLEDGE BY SLAVE
Figure 9. I2C Read Data Transfer
SDA
SLAVE ADDRESS
A6
SUB ADDRESS
A5
A7
STOP BIT
DATA
A0
D7
D0
SCK
S
WR
ACK
ACK
SLADDR[4...0]
ACK
SUB ADDR[6...1]
DATA[6...1]
Figure 10. I2C Data Transfer Timing
tF
tSU;DAT
tHD;STA
tBUF
SDA
tR
tR
tSU;STO
tF
tLOW
tHIGH
tHD;STA
S
tSU;STA
tHD;DAT
2
S
Figure 11. I C Port Timing Diagram
Rev. 0 | Page 10 of 24
P
S
05801-011
SCK
P
05801-010
START BIT
ADN2804
Table 6. Internal Register Map 1
Reg
Name
FREQ0
FREQ1
FREQ2
MISC
R/W
R
R
R
R
Addr
0x0
0x1
0x2
0x4
D7
MSB
MSB
0
x
CTRLA
CTRLB
W
W
0x8
0x9
CTRLC
W
0x11
FREF range
Config Reset
LOL
MISC[4]
0
0
1
D6
D5
D4
D3
MSB
x
LOS status
Static
LOL
LOL
status
System
reset
0
D2
D1
Data rate
measurement
complete
Data rate/DIV_FREF ratio
0
0
Reset
MISC[2]
0
0
Config LOS
x
D0
LSB
LSB
LSB
x
Measure data rate
0
Lock to reference
0
SQUELCH mode
Output boost
All writeable registers default to 0x00.
Table 7. Miscellaneous Register, MISC
D7
x
D6
x
LOS Status
D5
0 = No loss of signal
1 = Loss of signal
Static LOL
D4
0 = Waiting for next LOL
1 = Static LOL until reset
LOL Status
D3
0 = Locked
1 = Acquiring
Data Rate Measurement Complete
D2
0 = Measuring data rate
1 = Measurement complete
D1
x
D0
x
Table 8. Control Register, CTRLA 1
FREF Range
D7
D6
0
0
0
1
1
0
1
1
1
Data Rate/Div_FREF Ratio
D5
D4
D3
D2
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
19.44 MHz
38.88 MHz
77.76 MHz
155.52 MHz
32
32
32
32
Measure Data Rate
D1
Set to 1 to measure data rate
Lock to Reference
D0
0 = Lock to input data
1 = Lock to reference clock
Where DIV_FREF is the divided down reference referred to the 10 MHz to 20 MHz band (see the Reference Clock (Optional) section).
Table 9. Control Register, CTRLB
Config LOL
D7
0 = LOL pin normal operation
1 = LOL pin is static LOL
Reset MISC[4]
D6
Write a 1 followed
by 0 to reset MISC[4]
System Reset
D5
Write a 1 followed by
0 to reset ADN2804
D4
Set to 0
Reset MISC[2]
D3
Write a 1 followed
by 0 to reset MISC[2]
D2
Set to 0
D1
Set to 0
D0
Set to 0
Table 10. Control Register, CTRLC
D7
Set to 0
D6
Set to 0
D5
Set to 0
D4
Set to 0
D3
Set to 0
Config LOS
D2
0 = Active high LOS
1 = Active low LOS
Rev. 0 | Page 11 of 24
SQUELCH Mode
D1
0 = Squelch data outputs and
clock outputs
1 = Squelch data outputs or
clock outputs
Output Boost
D0
0 = Default output swing
1 = Boost output swing
ADN2804
TERMINOLOGY
OUTPUT
NOISE
1
10mV p-p
VREF
SCOPE
PROBE
ADN2804
PIN
+
QUANTIZER
–
50Ω
Figure 13. Single-Ended Sensitivity Measurement
When the ADN2804 is driven differentially (see Figure 14),
sensitivity seems to improve if observing the quantizer input
with an oscilloscope probe. This is an illusion caused by the use
of a single-ended probe. A 5 mV p-p signal appears to drive the
ADN2804 quantizer; however, the single-ended probe measures
only half the signal. The true quantizer input signal is twice this
value, because the other quantizer input is a complementary
signal to the signal being observed.
5mV p-p
0
INPUT (V p-p)
SCOPE
PROBE
PIN
+
OVERDRIVE
QUANTIZER
05801-012
SENSITIVITY
(2 × OVERDRIVE)
2.5V
3kΩ
VREF
OFFSET
50Ω
VREF
05801-013
Input Sensitivity and Input Overdrive
Sensitivity and overdrive specifications for the quantizer involve
offset voltage, gain, and noise. The relationship between the
logic output of the quantizer and the analog voltage input is
shown in Figure 12. For sufficiently large positive input voltage,
the output is always Logic 1; similarly, for negative inputs, the
output is always Logic 0. However, the transitions between
output Logic Level 1 and output Logic Level 0 are not at
precisely defined input voltage levels, but occur over a range of
input voltages. Within this range of input voltages, the output
may be either 1 or 0, or it may even fail to attain a valid logic
state. The width of this zone is determined by the input voltage
noise of the quantizer. The center of the zone is the quantizer
input offset voltage. Input overdrive is the magnitude of signal
required to guarantee the correct logic level with 1 × 10−10
confidence level.
NIN
–
Figure 12. Input Sensitivity and Input Overdrive
50Ω
VREF
50Ω
VREF
5mV p-p
3kΩ
2.5V
05801-014
Single-Ended vs. Differential
AC coupling is typically used to drive the inputs to the
quantizer. The inputs are internally dc biased to a commonmode potential of ~2.5 V. Driving the ADN2804 in a singleended fashion and observing the quantizer input with an
oscilloscope probe at the point indicated in Figure 13 shows a
binary signal with an average value equal to the common-mode
potential and instantaneous values both above and below the
average value. It is convenient to measure the peak-to-peak
amplitude of this signal and call the minimum required value
the quantizer sensitivity. Referring to Figure 13, the sensitivity is
twice the overdrive because both positive and negative offsets
need to be accommodated. The ADN2804 quantizer typically
has 3.3 mV p-p sensitivity.
Figure 14. Differential Sensitivity Measurement
LOS Response Time
LOS response time is the delay between removal of the input
signal and indication of loss of signal (LOS) at the LOS output,
Pin 22. When the inputs are dc-coupled, the LOS assert time of
the AD2804 is 500 ns typical and the deassert time is 400 ns
typical. In practice, the time constant produced by the ac
coupling at the quantizer input and the 50 Ω on-chip input
termination determines the LOS response time.
Rev. 0 | Page 12 of 24
ADN2804
JITTER SPECIFICATIONS
The ADN2804 CDR is designed to achieve the best biterror-rate (BER) performance and to exceed the jitter
transfer, generation, and tolerance specifications proposed
for SONET/SDH equipment defined in the Telcordia
Technologies specification.
Jitter Generation
The jitter generation specification limits the amount of jitter
that can be generated by the device with no jitter and wander
applied at the input. For SONET devices, the jitter generated
must be less than 0.01 UI rms and less than 0.1 UI p-p.
Jitter Transfer
The jitter transfer function is the ratio of the jitter on the output
signal to the jitter applied on the input signal vs. the frequency.
This parameter measures the amount of jitter on an input signal
that can be transferred to the output signal (see Figure 15). This
amount is limited.
05801-015
fC
JITTER FREQUENCY (kHz)
Figure 15. Jitter Transfer Curve
Jitter Tolerance
The jitter tolerance is defined as the peak-to-peak amplitude of
the sinusoidal jitter applied on the input signal, which causes a
1 dB power penalty. This is a stress test intended to ensure that
no additional penalty is incurred under the operating
conditions (see Figure 16).
15.00
SLOPE = –20dB/DECADE
1.50
0.15
f0
f1
f2
f3
JITTER FREQUENCY (kHz)
Figure 16. SONET Jitter Tolerance Mask
Rev. 0 | Page 13 of 24
f4
05801-016
The following sections briefly summarize the specifications of
jitter generation, transfer, and tolerance in accordance with the
Telcordia document (GR-253-CORE, Issue 3, September 2000)
for the optical interface at the equipment level and the
ADN2804 performance with respect to those specifications.
SLOPE = –20dB/DECADE
ACCEPTABLE
RANGE
INPUT JITTER AMPLITUDE (UI p-p)
Jitter is the dynamic displacement of digital signal edges from
their long-term average positions, measured in unit intervals
(UI), where 1 UI = 1 bit period. Jitter on the input data can
cause dynamic phase errors on the recovered clock sampling
edge. Jitter on the recovered clock causes jitter on the
retimed data.
JITTER GAIN (dB)
0.1
ADN2804
THEORY OF OPERATION
Another view of the circuit is that the phase shifter implements
the zero required for frequency compensation of a second-order
phase-locked loop, and this zero is placed in the feedback path;
therefore, it does not appear in the closed-loop transfer
function. Jitter peaking in a conventional second-order phaselocked loop is caused by the presence of this zero in the closedloop transfer function. Because this circuit has no zero in the
closed-loop transfer, jitter peaking is minimized.
The delay and phase loops together simultaneously provide
wideband jitter accommodation and narrow-band jitter
filtering. The linearized block diagram in Figure 17 shows that
the jitter transfer function, Z(s)/X(s), provides excellent secondorder low-pass filtering. Note that the jitter transfer has no zero,
unlike an ordinary second-order phase-locked loop. This means
that the main PLL loop has virtually no jitter peaking (see
Figure 18), making this circuit ideal for signal regenerator
applications, where jitter peaking in a cascade of regenerators
can contribute to hazardous jitter accumulation.
The error transfer, e(s)/X(s), has the same high-pass form as an
ordinary phase-locked loop. This transfer function can be
optimized to accommodate a significant amount of wideband
jitter, because the jitter transfer function, Z(s)/X(s), provides the
narrow-band jitter filtering.
INPUT
DATA
X(s)
e(s)
d/sc
o/s
1/n
Z(s)
RECOVERED
CLOCK
d = PHASE DETECTOR GAIN
o = VCO GAIN
c = LOOP INTEGRATOR
psh = PHASE SHIFTER GAIN
n = DIVIDE RATIO
JITTER TRANSFER FUNCTION
Z(s)
1
=
n psh
cn
X(s)
+1
s2
+s
o
do
TRACKING ERROR TRANSFER FUNCTION
05801-017
e(s)
s2
=
d psh do
X(s)
s2 + s
+
c
cn
Figure 17. PLL/DLL Architecture
JITTER PEAKING
IN ORDINARY PLL
ADN2804
Z(s)
X(s)
o
n psh
d psh
c
FREQUENCY (kHz)
05801-018
The delay and phase loops together track the phase of the input
data signal. For example, when the clock lags the input data, the
phase detector drives the VCO to a higher frequency and
increases the delay through the phase shifter; both of these
actions serve to reduce the phase error between the clock and
the data. The faster clock picks up phase, whereas the delayed
data loses phase. Because the loop filter is an integrator, the
static phase error is driven to 0°.
psh
JITTER GAIN (dB)
The ADN2804 is a delay- and phase-locked loop circuit for
clock recovery and data retiming from an NRZ encoded data
stream. The phase of the input data signal is tracked by two
separate feedback loops, which share a common control voltage.
A high speed delay-locked loop path uses a voltage controlled
phase shifter to track the high frequency components of input
jitter. A separate phase control loop, composed of the VCO,
tracks the low frequency components of input jitter. The initial
frequency of the VCO is set by yet a third loop that compares
the VCO frequency with the input data frequency and sets the
coarse tuning voltage. The jitter tracking phase-locked loop
controls the VCO by the fine-tuning control.
Figure 18. Jitter Response vs. Conventional PLL
The delay and phase loops contribute to overall jitter accommodation. At low frequencies of input jitter on the data signal,
the integrator in the loop filter provides high gain to track large
jitter amplitudes with small phase error. In this case, the VCO 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 VCO tuning range. A wider
tuning range gives larger accommodation of low frequency
jitter. The internal loop control voltage remains small for small
phase errors; therefore, the phase shifter remains close to the
center of its range and thus contributes little to the low
frequency jitter accommodation.
Rev. 0 | Page 14 of 24
ADN2804
At medium jitter frequencies, the gain and tuning range of the
VCO are not large enough to track input jitter. In this case, the
VCO control voltage becomes large and saturates, and the VCO
frequency dwells at one extreme of its tuning range. The size of
the VCO tuning range, therefore, has only a small effect on the
jitter accommodation. The delay-locked loop control voltage is
now larger; therefore, the phase shifter takes on the burden of
tracking the input jitter. The phase shifter range, in UI, can be
seen as a broad plateau on the jitter tolerance curve. The phase
shifter has a minimum range of 2 UI at all data rates.
The gain of the loop integrator is small for high jitter
frequencies; therefore, larger phase differences are needed to
increase the loop control voltage enough to tune the range of
the phase shifter. However, large phase errors at high jitter
frequencies cannot be tolerated. In this region, the gain of the
integrator determines the jitter accommodation. Because the
gain of the loop integrator declines linearly with frequency,
jitter accommodation is lower with higher jitter frequency. At
the highest frequencies, the loop gain is very small, and little
tuning of the phase shifter 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 generation.
The jitter accommodation is roughly 0.5 UI in this region. The
corner frequency between the declining slope and the flat region
is the closed-loop bandwidth of the delay-locked loop, which is
roughly 1.0 MHz at 622 Mbps.
Rev. 0 | Page 15 of 24
ADN2804
FUNCTIONAL DESCRIPTION
FREQUENCY ACQUISITION
LOSS-OF-SIGNAL (LOS) DETECTOR
The ADN2804 acquires frequency from the data. The lock
detector circuit compares the frequency of the VCO and the
frequency of the incoming data. When these frequencies differ
by more than 1000 ppm, LOL is asserted. This initiates a frequency
acquisition cycle. When the VCO frequency is within 250 ppm
of the data frequency, LOL is deasserted.
The receiver front-end LOS detector circuit detects when the
input signal level falls below a user-adjustable threshold. The
threshold is set with a single external resistor from Pin 9,
THRADJ, to VEE. The LOS comparator trip point vs. the
resistor value is shown in Figure 6. If the input level to the
ADN2804 drops below the programmed LOS threshold, the
output of the LOS detector, LOS (Pin 22), is asserted to Logic 1.
The LOS detector’s response time is ~500 ns by design, but is
dominated by the RC time constant in ac-coupled applications.
The LOS pin defaults to active high. However, setting Bit
CTRLC[2] to 1, configures the LOS pin as active low.
Once LOL is deasserted, the frequency-locked loop is turned
off. The PLL/DLL pulls the VCO frequency in the rest of the
way until the VCO frequency equals the data frequency.
The frequency loop requires a single external capacitor between
CF1 and CF2, Pin 14 and Pin 15. A 0.47 μF ± 20%, X7R ceramic
chip capacitor with <10 nA leakage current is recommended.
Leakage current of the capacitor can be calculated by dividing
the maximum voltage across the 0.47 μF capacitor, ~3 V, by the
insulation resistance of the capacitor. The insulation resistance
of the 0.47 μF capacitor should be greater than 300 MΩ.
There is typically 6 dB of electrical hysteresis designed into the
LOS detector to prevent chatter on the LOS pin. If the input
level drops below the programmed LOS threshold causing the
LOS pin to assert, the LOS pin deasserts after the input level
increases to 6 dB (2×) above the LOS threshold (see Figure 19).
LOS OUTPUT
INPUT LEVEL
HYSTERESIS
LOS THRESHOLD
t
05801-019
The limiting amplifier has differential inputs (PIN/NIN) that
are internally terminated with 50 Ω to an on-chip voltage
reference (VREF = 2.5 V typically). The inputs are typically
ac-coupled externally, although dc coupling is possible as long
as the input common-mode voltage remains above 2.5 V (see
Figure 27 to Figure 29 in the Applications Information section).
Input offset is factory trimmed to achieve better than 3.3 mV
typical sensitivity with minimal drift. The limiting amplifier can
be driven differentially or in a single-ended fashion.
INPUT VOLTAGE (VDIFF)
LIMITING AMPLIFIER
Figure 19. LOS Detector Hysteresis
SLICE ADJUST
The quantizer slicing level can be offset by ±100 mV to mitigate
the effect of amplified spontaneous emission (ASE) noise or duty
cycle distortion by applying a differential voltage input of up to
±0.95 V to the SLICEP and SLICEN inputs. If no adjustment of
the slice level is needed, SLICEP and SLICEN should be tied to
VEE. The gain of the slice adjustment is ~0.11 V/V.
The LOS detector and the SLICE level adjust can be used
simultaneously on the ADN2804. This means that any offset
added to the input signal by the SLICE adjust pins does not affect
the LOS detector’s measurement of the absolute input level.
Rev. 0 | Page 16 of 24
ADN2804
LOCK DETECTOR OPERATION
Static LOL Mode
The lock detector on the ADN2804 has three modes of
operation: normal mode, REFCLK mode, and static LOL mode.
The ADN2804 implements a static LOL feature that indicates if
a loss-of-lock condition has ever occurred. This feature remains
asserted, even if the ADN2804 regains lock, until the static LOL
bit is manually reset. The I2C register bit, MISC[4], is the static
LOL bit. If there is ever an occurrence of a loss-of-lock condition,
this bit is internally asserted to logic high. The MISC[4] bit remains
high even after the ADN2804 has reacquired lock to a new data
rate. This bit can be reset by writing a 1 followed by 0 to I2C
Register Bit CTRLB[6]. Once reset, the MISC[4] bit remains
deasserted until another loss-of-lock condition occurs.
Normal Mode
In normal mode, the ADN2804 is a CDR that locks onto a
622 Mbps data rate without the use of a reference clock as an
acquisition aid. In this mode, the lock detector monitors the
frequency difference between the VCO and the input data
frequency and deasserts the loss of lock signal, which appears
on Pin 16, LOL, when the VCO is within 250 ppm of the data
frequency. This enables the D/PLL, which pulls the VCO
frequency in the remaining amount and acquires phase lock.
Once locked, if the input frequency error exceeds 1000 ppm
(0.1%), the loss-of-lock signal is reasserted and control returns
to the frequency loop, which begins a new frequency
acquisition. The LOL pin remains asserted until the VCO locks
onto a valid input data stream to within 250 ppm frequency
error. This hysteresis is shown in Figure 20.
Writing a 1 to I2C Register Bit CTRLB[7] causes the LOL pin,
Pin 16, to become a static LOL indicator. In this mode, the LOL
pin mirrors the contents of the MISC[4] bit and has the
functionality described in the previous paragraph. The CTRLB[7]
bit defaults to 0. In this mode, the LOL pin operates in the
normal operating mode, that is, it is asserted only when the
ADN2804 is in acquisition mode and deasserts when the
ADN2804 has reacquired lock.
LOL
SQUELCH MODES
–1000
–250
0
250
1000
fVCO ERROR
(ppm)
05801-020
1
Figure 20. Transfer Function of LOL
LOL Detector Operation Using a Reference Clock
In REFCLK mode, a reference clock is used as an acquisition aid
to lock the ADN2804 VCO. Lock-to-reference mode is enabled
by setting CTRLA[0] to 1. The user also needs to write to the
CTRLA[7, 6] and CTRLA[5:2] bits to set the reference
frequency range and the divide ratio of the data rate with
respect to the reference frequency. For more details, see the
Reference Clock (Optional) section. In this mode, the lock
detector monitors the difference in frequency between the
divided down VCO and the divided down reference clock. The
loss-of-lock signal, which appears on Pin 16, LOL, is deasserted
when the VCO is within 250 ppm of the desired frequency. This
enables the D/PLL, which pulls the VCO frequency in the
remaining amount with respect to the input data and acquires
phase lock. Once locked, if the input frequency error exceeds
1000 ppm (0.1%), the loss-of-lock signal is reasserted and
control returns to the frequency loop, which reacquires with
respect to the reference clock. The LOL pin remains asserted
until the VCO frequency is within 250 ppm of the desired
frequency. This hysteresis is shown in Figure 20.
Two modes for the SQUELCH pin are available with the
ADN2804: squelch data outputs and clock outputs mode and
squelch data outputs or clock outputs mode. Squelch data outputs
and clock outputs mode is selected when CTRLC[1] is 0 (default
mode). In this mode, when the SQUELCH input, Pin 27, is driven
to a TTL high state, both the data outputs (DATAOUTN and
DATAOUTP) and the clock outputs (CLKOUTN and CLKOUTP)
are set to the zero state to suppress downstream processing. If
the squelch function is not required, Pin 27 should be tied to VEE.
Squelch data outputs or clock outputs mode is selected when
CTRLC[1] is 1. In this mode, when the SQUELCH input is
driven to a high state, the DATAOUTN and DATAOUTP pins
are squelched. When the SQUELCH input is driven to a low
state, the CLKOUTN and CLKOUTP pins are squelched. This is
especially useful in repeater applications, where the recovered
clock may not be needed.
I2C INTERFACE
The ADN2804 supports a 2-wire, I2C-compatible serial bus
driving multiple peripherals. Two inputs, serial data (SDA) and
serial clock (SCK), carry information to and from any device
connected to the bus. Each slave device is recognized by a
unique address. The ADN2804 has two possible 7-bit slave
addresses for both read and write operations. The MSB of the
7-bit slave address is factory programmed to 1. B5 of the slave
address is set by Pin 19, SADDR5. Slave Address Bits [4:0] are
defaulted to all 0s. The slave address consists of the seven MSBs
of an 8-bit word. The LSB of the word either sets a read or write
operation (see Figure 7). Logic 1 corresponds to a read operation,
while Logic 0 corresponds to a write operation.
Rev. 0 | Page 17 of 24
ADN2804
To control the device on the bus, the following protocol must be
followed. First, the master initiates a data transfer by establishing a start condition, defined by a high-to-low transition on
SDA while SCK remains high. This indicates that an address/
data stream follows. All peripherals respond to the start condition
and shift the next eight bits (the 7-bit address and the R/W bit).
The bits are transferred from MSB to LSB. The peripheral that
recognizes the transmitted address responds by pulling the data
line low during the ninth clock pulse. This is known as an
acknowledge bit. All other devices withdraw from the bus at
this point and maintain an idle condition. The idle condition is
where the device monitors the SDA and SCK lines, waiting for
the start condition and correct transmitted address. The R/W
bit determines the direction of the data. Logic 0 on the LSB of
the first byte means that the master writes information to the
peripheral. Logic 1 on the LSB of the first byte means that the
master reads information from the peripheral.
The ADN2804 acts as a standard slave device on the bus. The data
on the SDA pin is eight bits long, supporting the 7-bit addresses
plus the R/W bit. The ADN2804 has eight subaddresses to enable
the user-accessible internal registers (see Table 6 through Table
10). It, therefore, interprets the first byte as the device address
and the second byte as the starting subaddress. Auto-increment
mode is supported, allowing data to be read from or written to
the starting subaddress and each subsequent address without
manually addressing the subsequent subaddress. A data transfer
is always terminated by a stop condition. The user can also
access any unique subaddress register on a one-by-one basis
without updating all registers.
Stop and start conditions can be detected at any stage of the
data transfer. If these conditions are asserted out of sequence
with normal read and write operations, they cause an immediate
jump to the idle condition. During a given SCK high period, the
user should issue one start condition, one stop condition, or a
single stop condition followed by a single start condition. If an
invalid subaddress is issued by the user, the ADN2804 does not
issue an acknowledge and returns to the idle condition. If the
user exceeds the highest subaddress while reading back in autoincrement mode, then the highest subaddress register contents
continue to be output until the master device issues a no acknowledge. This indicates the end of a read. In a no-acknowledge
condition, the SDATA line is not pulled low on the ninth pulse.
See Figure 8 and Figure 9 for sample write and read data transfers
and Figure 10 for a more detailed timing diagram.
Additional Features Available via the I2C Interface
LOS Configuration
The LOS detector output, Pin 22, can be configured to be either
active high or active low. If CTRLC[2] is set to Logic 0 (default),
the LOS pin is active high when a loss-of-signal condition is
detected. Writing a 1 to CTRLC[2] configures the LOS pin to be
active low when a loss-of-signal condition is detected.
System Reset
A frequency acquisition can be initiated by writing a 1 followed
by a 0 to the I2C Register Bit CTRLB[5]. This initiates a new
frequency acquisition while keeping the ADN2804 in its
previously programmed operating mode, as set in Registers
CTRL[A], CTRL[B], and CTRL[C].
Rev. 0 | Page 18 of 24
ADN2804
REFERENCE CLOCK (OPTIONAL)
A reference clock is not required to perform clock and data
recovery with the ADN2804; however, support for an optional
reference clock is provided. The reference clock can be driven
differentially or in a single-ended fashion. If the reference
clock is not being used, REFCLKP should be tied to VCC, and
REFCLKN can be left floating or tied to VEE (the inputs are
internally terminated to VCC/2). See Figure 21 through Figure
23 for sample configurations.
The REFCLK input buffer accepts any differential signal with a
peak-to-peak differential amplitude of greater than 100 mV (for
example, LVPECL or LVDS) or a standard single-ended, low
voltage TTL input, providing maximum system flexibility.
Phase noise and duty cycle of the reference clock are not
critical, and 100 ppm accuracy is sufficient.
ADN2804
There are two mutually exclusive uses, or modes, of the
reference clock. The reference clock can be used either to help
the ADN2804 lock onto data or to measure the frequency of the
incoming data to within 0.01%. The modes are mutually
exclusive because in the first use the user knows exactly what
the data rate is and wants to force the part to lock onto only that
data rate, and in the second use the user does not know what
the data rate is and wants to measure it.
Lock-to-reference mode is enabled by writing a 1 to I2C Register
Bit CTRLA[0]. Fine data rate readback mode is enabled by
writing a 1 to I2C Register Bit CTRLA[1]. Writing a 1 to both of
these bits at the same time causes an indeterminate state and is
not supported.
Using the Reference Clock to Lock onto Data
In this mode, the ADN2804 locks onto a frequency derived
from the reference clock according to
REFCLKP
Data Rate/2CTRLA[5:2] = REFCLK/2CTRLA[7, 6]
10
BUFFER
The user must provide a reference clock that is a function of the
data rate. By default, the ADN2804 expects a reference clock of
19.44 MHz. Other options are 38.88 MHz, 77.76 MHz, and
155.52 MHz, which are selected by programming CTRLA[7, 6].
CTRLA[5:2] should be programmed to [0101] for all cases.
11
100kΩ
100kΩ
VCC/2
05801-021
REFCLKN
Figure 21. Differential REFCLK Configuration
VCC
CLK
OSC
REFCLKP
Table 11. CTRLA Settings
CTRLA[7, 6]
00
01
10
11
ADN2804
OUT
BUFFER
100kΩ
100kΩ
VCC/2
Figure 22. Single-Ended REFCLK Configuration
VCC
Ratio
25
25
25
25
622.08 Mbps/19.44 MHz = 25
In this mode, if the ADN2804 loses lock for any reason, it relocks
onto the reference clock and continues to output a stable clock.
BUFFER
11
100kΩ
VCC/2
05801-023
REFCLKN
100kΩ
CTRLA[5:2]
0101
0101
0101
0101
For example, if the reference clock frequency is 38.88 MHz and the
input data rate is 622.08 Mbps, CTRLA[7, 6] is set to [01] to
produce a divided-down reference clock of 19.44 MHz, and
CTRLA[5:2] is set to [0101], that is, 5, because
ADN2804
10
REFCLKP
NC
05801-022
REFCLKN
Range (MHz)
19.44
38.88
77.76
155.52
While the ADN2804 is operating in lock-to-reference mode,
a 0 to 1 transition should be written into the CTRLA[0] bit to
initiate a lock-to-reference clock command.
Figure 23. No REFCLK Configuration
Rev. 0 | Page 19 of 24
ADN2804
Using the Reference Clock to Measure Data Frequency
The user can also provide a reference clock to measure the
recovered data frequency. In this case, the user provides a
reference clock, and the ADN2804 compares the frequency of
the incoming data to the incoming reference clock and returns a
ratio of the two frequencies to within 0.01% (100 ppm) accuracy.
The accuracy error of the reference clock is added to the accuracy
of the ADN2804 data rate measurement. For example, if a 100 ppm
accuracy reference clock is used, the total accuracy of the measurement is within 200 ppm.
The reference clock can range from 10 MHz to 160 MHz.
By default, the ADN2804 expects a reference clock between
10 MHz and 20 MHz. If the reference clock is between 20 MHz
and 40 MHz, 40 MHz and 80 MHz, or 80 MHz and 160 MHz,
the user must configure the ADN2804 for the correct reference
frequency range by setting two bits of the CTRLA register,
CTRLA[7, 6]. Using the reference clock to determine the frequency
of the incoming data does not affect the manner in which the
part locks onto data. In this mode, the reference clock is used
only to determine the frequency of the data.
Prior to reading back the data rate using the reference clock, the
CTRLA[7, 6] bits must be set to the appropriate frequency
range with respect to the reference clock being used. A fine data
rate readback is then executed as follows:
1. Write a 1 to CTRLA[1]. This enables the fine data rate
measurement capability of the ADN2804. This bit is level
sensitive and can perform subsequent frequency measurements
without being reset.
2. Reset MISC[2] by writing a 1 followed by a 0 to CTRLB[3].
This initiates a new data rate measurement.
3. Read back MISC[2]. If it is 0, the measurement is not
complete. If it is 1, the measurement is complete and the
data rate can be read back on FREQ[22:0]. The time for a
data rate measurement is typically 80 ms.
4. Read back the data rate from FREQ2[6:0], FREQ1[7:0], and
FREQ0[7:0].
The data rate can be determined by
f DATARATE = (FREQ [22.0] × f REFCLK ) / 2 (14 + SEL _ RATE)
where:
FREQ[22:0] is the reading from FREQ2[6:0] (MSB byte,
FREQ1[7:0], and FREQ0[7:0] (LSB byte).
fDATARATE is the data rate (Mbps).
fREFCLK is the REFCLK frequency (MHz).
SEL_RATE is the setting from CTRLA[7, 6].
For example, if the reference clock frequency is 32 MHz,
SEL_RATE = 1, because the reference frequency falls into the
20 MHz to 40 MHz range, setting CTRLA[7, 6] to [01],.
Assume for this example that the input data rate is 622.08 Mb/s
(OC12). After following Step 1 through Step 4, the value that is
read back on FREQ[22:0] = 0x9B851, which is equal to 637 × 103.
Plugging this value into the equation yields
637e3 × 32e6/2(14 + 1) = 622.08 Mbps
If subsequent frequency measurements are required, CTRLA[1]
should remain set to 1. It does not need to be reset. The
measurement process is reset by writing a 1 followed by a 0 to
CTRLB[3]. This initiates a new data rate measurement. Follow
Step 2 through Step 4 to read back the new data rate.
Note that a data rate readback is valid only if LOL is low. If LOL
is high, the data rate readback is invalid.
Table 12.
D22
D21 ... D17
FREQ2[6:0]
D16
D15
D14 ... D9
FREQ1[7:0]
Rev. 0 | Page 20 of 24
D8
D7
D6 ... D1
FREQ0[7:0]
D0
ADN2804
APPLICATIONS INFORMATION
PCB DESIGN GUIDELINES
If connections to the supply and ground are made through
vias, the use of multiple vias in parallel helps to reduce series
inductance, especially on Pin 24, which supplies power to the
high speed CLKOUTP/CLKOUTN and DATAOUTP/
DATAOUTN output buffers. Refer to Figure 24 for the
recommended connections.
Proper RF PCB design techniques must be used for optimal
performance.
Power Supply Connections and Ground Planes
Use of one low impedance ground plane is recommended. The
VEE pins should be soldered directly to the ground plane to
reduce series inductance. If the ground plane is an internal
plane and connections to the ground plane are made through
vias, multiple vias can be used in parallel to reduce the series
inductance, especially on Pin 23, which is the ground return for
the output buffers. The exposed pad should be connected to the
GND plane using plugged vias so that solder does not leak
through the vias during reflow.
By placing the power supply and GND planes adjacent to each
other and using close spacing between the planes, excellent high
frequency decoupling can be realized. The capacitance is given
by
C PLANE = 0.88ε r A/d (pF)
Use of a 22 μF electrolytic capacitor between VCC and VEE is
recommended at the location where the 3.3 V supply enters the
PCB. When using 0.1 μF and 1 nF ceramic chip capacitors, they
should be placed between ADN2804 supply pins VCC and VEE,
as close as possible to the ADN2804 VCC pins.
where:
εr is the dielectric constant of the PCB material.
A is the area of the overlap of power and GND planes (cm2).
d is the separation between planes (mm).
For FR-4, εr = 4.4 and d = 0.25 mm; therefore,
CPLANE ~ 15.5A (pF)
50Ω TRANSMISSION LINES
VCC
DATAOUTP
+
22µF
0.1µF
DATAOUTN
1nF
CLKOUTP
TEST2
VCC
VEE
DATAOUTP
DATAOUTN
SQUELCH
CLKOUTP
CLKOUTN
CLKOUTN
TIA
50Ω
1.6µF
50Ω
1.6µF
32
31
30
29
28
27
26
25
1nF
VCC
VEE
LOS
SDA
SCK
SADDR5
VCC
VEE
1nF
0.1µF
I2C CONTROLLER
I2C CONTROLLER
µC
VCC
0.1µF
µC
RTH
VCC
0.1µF
1nF
0.47µF ±20%
>300MΩ INSULATION RESISTANCE
Figure 24. Typical ADN2804 Applications Circuit
Rev. 0 | Page 21 of 24
05801-031
0.1µF
24
EXPOSED PAD 23
TIED OFF TO 22
VEE PLANE 21
20
WITH VIAS
19
18
17
9
10
11
12
13
14
15
16
1nF
1
2
3
4
5
6
7
8
THRADJ
REFCLKP
REFCLKN
NC
VCC
VEE
CF2
CF1
LOL
0.1µF
TEST1
VCC
VREF
NIN
PIN
SLICEP
SLICEN
VEE
VCC
ADN2804
Transmission Lines
Choosing AC Coupling Capacitors
Minimizing reflections in the ADN2804 requires use of 50 Ω
transmission lines for all pins with high frequency input and
output signals, including PIN, NIN, CLKOUTP, CLKOUTN,
DATAOUTP, and DATAOUTN (also REFCLKP and REFCLKN,
if a high frequency reference clock is used, such as 155 MHz). It
is also necessary for the PIN/NIN input traces to be matched in
length and for the CLKOUTP/CLKOUTN and
DATAOUTP/DATAOUTN output traces to be matched in
length to avoid skew between the differential traces.
AC coupling capacitors at the input (PIN, NIN) and output
(DATAOUTP, DATAOUTN) of the ADN2804 can be optimized
for the application. When choosing the capacitors, the time
constant formed with the two 50 Ω resistors in the signal path
must be considered. When a large number of consecutive
identical digits (CIDs) are applied, the capacitor voltage can
droop due to baseline wander (see Figure 26), causing patterndependent jitter (PDJ).
The high speed inputs, PIN and NIN, are internally terminated
with 50 Ω to an internal reference voltage (see Figure 25).
A 0.1 μF is recommended between VREF, Pin 3, and GND to
provide an ac ground for the inputs.
The user must determine how much droop is tolerable and
choose an ac coupling capacitor based on that amount of droop.
The amount of PDJ can then be approximated based on the
capacitor selection. The actual capacitor value selection can
require some trade-offs between droop and PDJ.
As with any high speed, mixed-signal design, take care to keep
all high speed digital traces away from sensitive analog nodes.
For example, assuming that 2% droop can be tolerated, the
maximum differential droop is 4%. Normalizing to V p-p:
Droop = ΔV = 0.04 V = 0.5 V p-p (1 − e−t/τ); therefore, τ = 12t
VCC
ADN2804
CIN
PIN
50Ω
CIN
NIN
TIA
0.1µF
VREF
3Ω
where:
τ is the RC time constant (C is the ac coupling capacitor, R =
100 Ω seen by C).
t is the total discharge time, which is equal to nT, where n is the
number of CIDs, and T is the bit period.
2.5V
The capacitor value can then be calculated by combining the
equations for τ and t:
05801-026
50Ω
Figure 25. ADN2804 AC-Coupled Input Configuration
C = 12 nT/R
Soldering Guidelines for Lead Frame Chip Scale Package
The lands on the 32-lead LFCSP are rectangular. The printed
circuit board (PCB) pad for these should be 0.1 mm longer than
the package land length and 0.05 mm wider than the package
land width. The land should be centered on the pad. This
ensures that the solder joint size is maximized. The bottom of
the chip scale package has a central exposed pad. The pad on
the PCB should be at least as large as this exposed pad. The user
must connect the exposed pad to VEE using plugged vias so
that solder does not leak through the vias during reflow. This
ensures a solid connection from the exposed pad to VEE.
Once the capacitor value is selected, the PDJ can be
approximated as
PDJpspp = 0.5 tr(1 − e(−nT/RC))/0.6
where:
PDJpspp is the amount of pattern-dependent jitter allowed
(<0.01 UI p-p typical).
tr is the rise time, which is equal to 0.22/BW,
where BW ~ 0.7 (bit rate).
Note that this expression for tr is accurate only for the inputs.
The output rise time for the ADN2804 is ~100 ps regardless of
the data rate.
Rev. 0 | Page 22 of 24
ADN2804
VCC
V1
CIN
V2
ADN2804
PIN
TIA
V1b CIN V2b
50Ω
VREF
1
2
DATAOUTP
CDR
LIMAMP
DATAOUTN
COUT
–
NIN
V1
COUT
+
50Ω
3
4
V1b
V2
VREF
V2b
VTH
VDIFF
VDIFF = V2–V2b
VTH = ADN2804 QUANTIZER THRESHOLD
05801-027
NOTES:
1. DURING DATA PATTERNS WITH HIGH TRANSITION DENSITY, DIFFERENTIAL DC VOLTAGE AT V1 AND V2 IS ZERO.
2. WHEN THE OUTPUT OF THE TIA GOES TO CID, V1 AND V1b ARE DRIVEN TO DIFFERENT DC LEVELS. V2 AND V2b DISCHARGE TO THE
VREF LEVEL, WHICH EFFECTIVELY INTRODUCES A DIFFERENTIAL DC OFFSET ACROSS THE AC COUPLING CAPACITORS.
3. WHEN THE BURST OF DATA STARTS AGAIN, THE DIFFERENTIAL DC OFFSET ACROSS THE AC COUPLING CAPACITORS IS APPLIED TO
THE INPUT LEVELS CAUSING A DC SHIFT IN THE DIFFERENTIAL INPUT. THIS SHIFT IS LARGE ENOUGH SUCH THAT ONE OF THE STATES,
EITHER HIGH OR LOW DEPENDING ON THE LEVELS OF V1AND V1b WHEN THE TIA WENT TO CID, IS CANCELED OUT. THE QUANTIZER
DOES NOT RECOGNIZE THIS AS A VALID STATE.
4. THE DC OFFSET SLOWLY DISCHARGES UNTIL THE DIFFERENTIAL INPUT VOLTAGE EXCEEDS THE SENSITIVITY OF THE ADN2804. THE
QUANTIZER CAN RECOGNIZE BOTH HIGH AND LOW STATES AT THIS POINT.
Figure 26. Example of Baseline Wander
PIN
VSE = 5mV MIN
NIN
PIN
PIN
VCM = 2.3V MIN
(DC-COUPLED)
Figure 28. Minimum Allowed DC-Coupled Input Levels
VCC
50Ω
V p-p = PIN – NIN = 2 × VSE = 10mV AT SENSITIVITY
05801-029
The inputs to the ADN2804 can also be dc-coupled. This may
be necessary in burst mode applications, where there are long
periods of CIDs, and baseline wander cannot be tolerated. If the
inputs to the ADN2804 are dc-coupled, care must be taken not
to violate the input range and common-mode level requirements of the ADN2804 (see Figure 27 through Figure 29). If dc
coupling is required and the output levels of the TIA do not
adhere to the levels shown in Figure 28, level shifting must be
performed and/or an attenuator must be placed between the
TIA outputs and the ADN2804 inputs.
INPUT (V)
DC-COUPLED APPLICATION
V p-p = PIN – NIN = 2 × VSE = 2.0V MAX
ADN2804
INPUT (V)
VSE = 1.0V MAX
TIA
NIN
0.1µF
VREF
50Ω
3kΩ
NIN
2.5V
05801-030
50Ω
VCM = 2.3V
(DC-COUPLED)
05801-028
50Ω
Figure 27. DC-Coupled Application
Figure 29. Maximum Allowed DC-Coupled Input Levels
Rev. 0 | Page 23 of 24
ADN2804
OUTLINE DIMENSIONS
0.60 MAX
5.00
BSC SQ
0.60 MAX
25
24
PIN 1
INDICATOR
TOP
VIEW
0.50
BSC
4.75
BSC SQ
0.50
0.40
0.30
12° MAX
1.00
0.85
0.80
PIN 1
INDICATOR
32
1
EXPOSED
PAD
(BOTTOM VIEW)
17
16
3.45
3.30 SQ
3.15
9
8
0.25 MIN
3.50 REF
0.80 MAX
0.65 TYP
0.05 MAX
0.02 NOM
SEATING
PLANE
0.30
0.23
0.18
0.20 REF
COPLANARITY
0.08
COMPLIANT TO JEDEC STANDARDS MO-220-VHHD-2
Figure 30. 32-Lead Frame Chip Scale Package [LFCSP_VQ]
5 mm × 5 mm Body, Very Thin Quad
(CP-32-3)
Dimensions shown in millimeters
ORDERING GUIDE
Model
ADN2804ACPZ 1
ADN2804ACPZ-500RL71
ADN2804ACPZ-RL71
EVAL-ADN2804EB
1
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
32-Lead LFCSP_VQ
32-Lead LFCSP_VQ, Tape-Reel, 500 pieces
32-Lead LFCSP_VQ, Tape-Reel, 1500 pieces
Evaluation Board
Package Option
CP-32-3
CP-32-3
CP-32-3
Z = Pb-free part.
Purchase of licensed I2C components of Analog Devices or one of its sublicensed Associated Companies conveys a license for the purchaser under the Philips I2C Patent
Rights to use these components in an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips.
©2006 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D05801–0–2/06(0)
Rev. 0 | Page 24 of 24