MICREL SY89537LMG

SY89537L
3.3V Precision LVPECL and LVDS
Programmable Multiple Output Bank Clock
Synthesizer and Fanout Buffer
General Description
The SY89537L integrated programmable clock
synthesizer and fanout is part of a precision PLLbased clock generation family optimized for enterprise
switch, router, and multiprocessor server applications.
This family is ideal for generating internal system
timing requirements up to 700MHz for multiple ASICs,
FPGAs, and NPUs. These devices integrate the
following blocks into a single monolithic IC:
•
PLL (Phase-Lock-Loop) based synthesizer
•
Fanout buffers
•
Clock generator (dividers)
•
Logic translation (LVPECL, LVDS)
•
Five independently programmable output
banks
This level of integration minimizes additive jitter and
part-to-part skew associated with discrete alternatives,
resulting in superior system-level timing with reduced
board space and power. For applications that require
a zero-delay function, see the SY89538L.
All support documentation can be found on
Micrel’s web site at: www.micrel.com.
Applications
• Enterprise routers, switches, servers and
workstations
• Parallel processor-based systems
• Internal system clock generation for ASICs, NPUs,
FPGAs
Markets
• LAN/WAN
• Enterprise servers
• Test and measurement
Precision Edge®
Features
• Integrated programmable synthesizer with multiple
output dividers, fanout buffers, and clock drivers
• Direct interface to crystal: 14MHz to 18MHz
• Input MUX accepts a reference and a crystal
(XTAL) source
– Ideal for reference backup clock source or
system test frequency source
– Patent-pending unique input MUX isolates XTAL
and reference inputs minimizes crosstalk
• Guaranteed AC performance:
– 87.15MHz to 700MHz output frequency range
(with RFCK at 16.6MHz)
– <100psPP total jitter
– <7psRMS cycle-to-cycle jitter
– <8psPP deterministic jitter
– <0.7psRMS crosstalk induced jitter
– <50ps bank-to-bank skew
• Output bank synchronization control pin
• LVPECL and LVDS outputs
• TTL/CMOS compatible control logic
• Five independently programmable output
frequency banks:
– Four differential LVPECL output banks
– One differential LVDS output bank with 3 output
pairs
• Separate output enable for each bank
• 3.3V ±10% power supply (2.5V output capable)
• Guaranteed over the commercial and industrial
temperature range (-40C to +85C)
• Available in 44-pin (7mm x 7mm) MLF™ package
Precision Edge is a registered trademark of Micrel, Inc.
MLF and MicroLeadFrame are trademarks of Amkor Technology, Inc.
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
August 2005
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SY89537L
Functional Block Diagram
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Ordering Information(1)
Package Marking
Lead
Finish
Industrial
SY89537LMG with
Pb-Free bar-line indicator
NiPdAu
Pb-Free
Industrial
SY89537LMG with
Pb-Free bar-line indicator
NiPdAu
Pb-Free
Part Number
Package
Type
Operating
Range
SY89537LMG
MLF-44
SY89537LMGTR(2)
MLF-44
Notes:
1. Contact factory for die availability. Dice are guaranteed at TA = 25°C, DC Electricals only.
2. Tape and Reel.
Pin Configuration
44-Pin MLFTM (MLF-44)
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Pin Description
Power
Pin Number
1
3
Pin Name
VCCA
VCCD
Pin Function
Analog PLL Power Pin: Connects to “quiet” 3.3V supply. 3.3V power pins are not internally
connected on the die, and must be connected together on the PCB. Bypass with
0.1µF//0.01µF low ESR capacitors and place as close to the VCCA pin as possible.
Digital Logic Core Power Pin: VCCD connects to a 3.3V supply. Power pins are not internally
connected on the die, and must be connected together on the PCB. Bypass with
0.1µF//0.01µF low ESR capacitors and place bypass capacitors as close to the VCCD pin as
possible.
14, 27, 30, 36
VCCO
LVDS and LVPECL Output Driver Power Pins: The outputs can be powered from a 2.5V
supply or 3.3V supply. Connect all VCCO pins to the same power supply: 3.3V ±10% or 2.5V
±5%. Power pins are not internally connected on the die, and must be connected together on
the PCB. Bypass with 0.1µF//0.01µF low ESR capacitor and place as close to the VCCO pin
as possible.
10
GNDA
PLL Ground: Connect to “quiet” ground. GNDA and GND are not internally connected on the
die, and must be connected on the PCB.
11, 21, 22
GND,
Exposed Pad
Ground: GND pins and exposed pad must both be connected to the most negative potential
of the chip ground.
Control and Configuration
Pin Number
Pin Name
43
LR
Analog Input/Output: Provides the reference voltage for the PLL loop filter and is used with the
LF pin. See "External Loop Filter Considerations" for recommended loop filter values.
44
LF
Analog Input/Output: Provides the loop filter node for the PLL. See “External Loop Filter
Considerations” for loop filter values.
2, 4
RSEL1, RSEL0
7
INSEL
TTL/CMOS Input Select Control. Selects either XTAL or Reference (RFCK) input. Internal
25kΩ pull-up. The default is logic HIGH, and selects the XTAL input. The threshold voltage VTH
= VCC/2.
Logic HIGH: XTAL Select
Logic LOW: Reference Input Select
23
LSEL
TTL/CMOS input select control signal for the LVDS LOUT0-LOUT2 outputs. LSEL and LEN
are used to decode the selection and the post divider of the LVDS output bank. LSEL includes
an internal 25kΩ pull-up. See “LVDS Output and Frequency Select Table” for proper decoding.
The threshold voltage VTH = VCC/2.
24
LEN
TTL/CMOS Input Enable Pin. Used to control the LOUT0-LOUT2 outputs and acts as a
frequency select pin. LEN and LSEL are used to decode the selection and the post divider of
the LVDS output bank. See the “LVDS Output and Frequency Select Table” for proper
decoding. LEN includes an internal 25kΩ pull-up. When disabled, LOUT0-LOUT2 outputs are
LOW, and the complimentary outputs are HIGH. The threshold voltage VTH = VCC/2.
17
19
39
41
PSEL0
PSEL1
PSEL2
PSEL3
TTL/CMOS input select control signals for the PECL POUT0-POUT3 outputs. PSELx and
PENx are used together to decode the selection and post divider of the PECL outputs. PSELx
pins include an internal 25kΩ pull-up. The threshold voltage VTH = VCC/2. See "PECL Output
Frequency and Select Table" for proper decoding.
18
20
40
42
PEN0
PEN1
PEN2
PEN3
TTL/CMOS input enable pin. Used to control the POUT0-PECL2 outputs and acts as a
frequency select pins. PENx and PSELx are used together; see the “PECL Output and
Frequency Select Table” for proper decoding. PENx includes an internal 25kΩ pull-up. When
disabled, PECL0-PECL2 outputs are LOW. The threshold voltage VTH = VCC/2.
33
SYNC
TTL/CMOS output bank synchronization control. Internal 25kΩ pull-up. The default state is
HIGH. After any bank has been programmed, all PECL and LVDS outputs are synchronized
when the SYNC control pin is toggled with a HIGH-LOW-HIGH transition. See
“Synchronization” section for details. The threshold voltage VTH = VCC/2.
August 2005
Pin Function
TTL/CMOS Reference Input Pre-scaler. The two-bit input pre-scaler divides the input
reference frequency by /1, /2, /4, or /8. RSEL0 is the LSB bit. See "Reference Input Divider
Select Table," for proper decoding. The threshold voltage VTH = VCC/2. Internal 25kΩ pull-up.
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Pin Description (continued)
Input/Output
Pin Number
Pin Name
5, 6
RFCK, /RFCK
Pin Function
Reference Clock Differential Input. Input accepts any input, single-ended or differential:
TTL/CMOS, LVPECL, LVDS, HSTL, and SSTL. RFCK requires external termination.
See "Input Interface" section for details.
XTAL2, XTAL1
Crystal Input. Directly connect a series resonant crystal across inputs. See “Quartz
Crystal Oscillator Specification” table. Place crystal as close to the input as possible,
keep XTAL and traces away from adjacent noisy traces to minimize noise coupling, and
place the XTAL on the same side as the SY89537L (component side).
12, 13
15, 16
34, 35
37, 38
POUT0, /POUT0
POUT1, /POUT1
POUT2, /POUT2
POUT3, /POUT3
100K LVPECL Output Drivers. Terminate all PECL outputs with 50Ω to VCCO-2V. Each
output pair has respective output frequency control (PSELx, PENx) pins. See "PECL
Output and Frequency Select Table" for proper coding. For low jitter applications, unused
PECL output pairs should be terminated with pull-down resistors. See "Output
Termination Recommendations" section for termination detail.
25, 26
28, 29
31, 32
LOUT0, /LOUT0
LOUT1, /LOUT1
LOUT2, /LOUT2
Differential LVDS Compatible Output Drivers. Output termination is 100Ω across the pair.
For low-jitter applications, unused LVDS output pairs should be terminated with 100Ω
across the pair. See “Output Termination Recommendations” section for details.
8, 9
Reference Input Driver Select Table
RSEL1
RSEL0
Internal Reference
Clock
0
0
RFCK / 8
0
1
RFCK / 4
1
0
RFCK / 2
1
1
RFCK / 1
Table 1. Reference Input Divider Select Table
Output and Frequency Select Tables
PSELx
PENx
POUTx
0
0
Disable Output
0
1
(VCO/4) / 2
1
0
(VCO/4) / 8
1
1
(VCO/4) / 1
Table 2. PECL Output and Frequency Select Table
LSEL
LEN
LOUTx
0
0
Disable Output
0
1
(VCO/4) / 2
1
0
(VCO/4) / 8
1
1
(VCO/4) / 1
Table 3. LVDS Output and Frequency Select Table
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Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VCC) .......................... –0.5V to +4.0V
Input Voltage (VIN) .................................. –0.5V to VCC
XTAL Input Voltage (VXTAL1, 2) ......... VCC –1.9V to VCC
Output Current (IOUT)
LVPECL Outputs ......................................±50mA
LVDS Outputs...........................................±10mA
Lead Temperature (soldering, 20 sec.) .......... +260°C
Storage Temperature (Ts) ................. –65°C to 150°C
Supply Voltage (VCCD, VCCA) ...................... +3.0V to +3.6V
Supply Voltage (VCCO)........................... +2.375V to +3.6V
Ambient Temperature (TA)....................... –40°C to +85°C
Package Thermal Resistance(3)
MLF™ (θJA)
Still-Air.........................................................24°C/W
MLF™ (ψJB)
Junction-to-Board..........................................8°C/W
DC Electrical Characteristics(4)
Power Supply
TA = –40°C to +85°C, unless otherwise stated.
Symbol
Parameter
Condition
Min
Typ
Max
Units
VCCA
PLL Power Supply
Note 5
3.0
3.3
3.6
V
VCCD
Control Logic Supply Voltage
Note 5
3.0
3.3
3.6
V
VCCO
Output Supply Voltage
2.375
2.5
2.625
V
3.3
3.6
V
ICC
Total Power Supply Current
No load, max. VCC, Note 6
240
300
mA
ICCA
Analog Supply Current
Max. VCC
10
mA
ICCO
Output Supply Current
No load, max. VCC
55
mA
ICCD
Digital Supply Current
Max. VCC
175
mA
3.0
LVCMOS/LVTTL Input Control Logic
VCCA = VCCD +3.3V ±10%, VCCO = +2.5V ±5% or +3.3V ±10%; TA = –40°C to +85°C, unless otherwise stated.
Symbol
Parameter
Condition
Min
VIH
Input High Voltage
VIL
Input Low Voltage
IIH
Input High Current
VIN = VCC
–125
IIL
Input Low Current
VIN = 0.5V
–300
Typ
Max
2.0
Units
V
0.8
V
150
µA
µA
Notes:
1. Permanent device damage may occur if absolute maximum ratings are exceeded. This is a stress rating only and functional operation is not
implied at conditions other than those detailed in the operational sections of this data sheet. Exposure to absolute maximum ratings
conditions for extended periods may affect device reliability.
2. The data sheet limits are not guaranteed if the device is operated beyond the operating ratings.
3. Package thermal resistance assumes exposed pad is soldered (or equivalent) to the devices most negative potential on the PCB. θJA and
ΨJB values are determined for a 4-layer board in still-air, unless otherwise stated.
4. The circuit is designed to meet the DC specifications shown in the above table after thermal equilibrium has been established.
5. VCCA and VCCD are not internally connected. They must be connected together on the PCB.
6. ICC = ICCA + ICCO + ICCD.
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Reference Clock Input
VCCA = VCCD +3.3V ±10%, VCCO = +2.5V ±5% or +3.3V ±10%; TA = –40°C to +85°C, unless otherwise stated.
Symbol
Parameter
Condition
Min
Typ
Max
Units
VIH
Input HIGH Voltage
RFCK, /RFCK
VCCD + 0.3
V
VIL
Input LOW Voltage
RFCK, /RFCK
–0.3
V
VIN
Input Voltage Swing
RFCK, /RFCK,
See Figure 1a.
100
mV
VDIFF-IN
Differential Input Voltage Swing
RFCK, /RFCK,
See Figure 1b.
200
mV
LVPECL Output DC Electrical Characteristics
VCCA = VCCD +3.3V ±10%, VCCO = +2.5V ±5% or +3.3V ±10%, RL = 50Ω into VCCO–2V; TA = –40°C to +85°C, unless
otherwise stated.
Symbol
Parameter
Max
Units
VOH
Output HIGH Voltage
Condition
VCCO –1.075
Min
Typ
VCCO –0.830
V
VOL
Output LOW Voltage
VCCO –1.860
VCCO –1.570
V
VOUT
Output Voltage Swing
See Figure 1a.
550
800
mV
VDIFF-OUT
Differential Output Voltage Swing
See Figure 1b.
1100
1600
mV
LVDS Output DC Electrical Characteristics
VCCA = VCCD +3.3V ±10%, VCCO = +2.5V ±5% or +3.3V ±10%, RL = 100Ω across the pair; TA = –40°C to +85°C,
unless otherwise stated.
Symbol
Parameter
Condition
Min
Typ
Max
Units
VOUT
Output Voltage Swing
See Figure 1a.
250
325
mV
VDIFF-OUT
Differential Output Voltage Swing
See Figure 1b.
500
650
mV
VOCM
Output Common Mode Voltage
∆VOCM
Change in Common Mode Voltage
August 2005
1.125
7
1.275
V
25
mV
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AC Electrical Characteristics
VCCA = VCCD = +3.3V ±10%; VCCO = +2.5V ±5% or +3.3V ±10%, RL (LVDS) = 100Ω across the output, RL (LVPECL)
= 50Ω into VCCO–2V; TA = –40°C to +85°C, unless otherwise stated.
Symbol
fIN
fPHASE
fOUT
fVCO
tSKEW
tLOCK
tJITTER
BW
tDC
tr, tf
Parameter
XTAL Input Frequency Range
Reference Input Frequency Range
Phase Detector Operating Frequency Range
Output Frequency Range
Internal VCO Frequency Range
LVPECL Output Banks (0–3), Bank-to-Bank
LVDS Output Banks (0–2), Bank-to-Bank
Part-to-Part Skew
Condition
Note 7
Min
14
14
14
73.5
2352
Note 8
Typ
15
15
Note 9
PLL Lock Time
Loop Filter Optimized for Cycle-to-Cycle Jitter
• R = 130Ω
• C1 = 0.47µF
• C2 = 100pF
1-Sigma Cycle-to-Cycle Jitter (XTAL Reference)
1-Sigma Cycle-to-Cycle Jitter (RFCK Reference)
Deterministic Jitter
Total Jitter
Spur
Note 10
Note 10
Note 11
Note 12
XTAL/RFCK Crosstalk-Induced Jitter
PLL Bandwidth
FOUT Duty Cycle
Output Rise/Fall Time (20% to 80%) LVPECL
Output Rise/Fall Time (20% to 80%) LVDS
Note 13
See “PLL Stability” Table
See “Synchronization”
4
5
5.5
80
-35
28.8
43
100
80
8
50
250
150
tPW_SYNC_MIN
See “Synchronization”
8
tPD_SYNC
Max
18
144
18
756
3024
50
50
200
10
Units
MHz
MHz
MHz
MHz
MHz
ps
ps
ps
ms
6
7
8
100
psRMS
psRMS
psPP
psPP
dBc@
fphase
0.7
99.8
57
400
300
psRMS
kHz
%
ps
ps
Internal
clock
cycle
Internal
clock
cycle
Notes:
7.
Fundamental mode, series resonant crystal.
8.
The bank-to-bank skew is defined as the worst-case difference between any two similar delay paths within a single device operating at the
same voltage and temperature.
9.
Part-to-part skew is defined for two parts with identical power supply voltages at the same temperature and with no skew of the edges at
the respective inputs.
10. Cycle-to-cycle jitter definition: the variation of periods between adjacent cycles, Tn – Tn-1 where T is the time between rising edges of the
output signal.
23
11. Deterministic jitter is measured at 2.5Gbps with both K28.5 and 2 -1 PRBS pattern.
12
12. Total jitter definition: with an ideal clock input of frequency <fMAX, no more than one output edge in 10 output edges will deviate by more
than the specified peak-to-peak jitter value.
13. Crosstalk is measured at the output while applying two similar differential clock frequencies that are asynchronous with respect to each
other at the inputs.
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Single-Ended and Differential Swings
Figure 1b. Differential Voltage Swing
Figure 1a. Single-Ended Voltage Swing
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Oscillator Tips
1. Mount the crystal as close to the SY89537L
as possible to minimize parasitic effects.
2. Mount on the same plane as the SY89537 to
minimize on via hole inductance.
3. To minimize noise pick up on the loop filter
pins, cut the ground plane directly underneath
the loop filter component pads and traces.
4. Keep the crystal and its traces away from
adjacent noisy traces to minimize on noise
coupling.
Functional Description
Overall Function
The SY89537L integrated programmable clock
synthesizer and fanout buffer is part of a precision
PLL-based clock generation family optimized for
internal system clock generation for (FPGAs, ASICs,
NPU) applications.
Input MUX
The device’s input patent-pending MUX accepts both
a single-ended or differential reference clock; and a
14MHz to 18MHz series resonant crystal (XTAL). The
input MUX has built-in isolation, which minimizes
crosstalk between the two inputs. The input MUX
drives the PLLs phase detector, which expects a
frequency between 14MHz and 18MHz, therefore, the
reference clock can be a maximum frequency of
144MHz when the reference divider is set to: divideby-8. The minimum frequency that the reference
accepts is 14MHz when the reference divider is set at:
divide-by-1.
Table 4 illustrates the crystal specifications. Figure 2
below illustrates how to interface the crystal with the
SY89537L.
Figure 2. Crystal Interface
PLL VCO
The VCOs range of operation is from 2.352GHz to
3.024GHz, and the output frequency range is from
73.5MHz to 756MHz. The minimum output frequency
is calculated according to the following equation:
fOUT =
Quartz Crystal Selection:
Note: Raltron Series Resonant: AS-16.666-S-SMD-T-MI (2) Raltron
External Loop Filter Considerations
The SY89537L features an external PLL loop filter
that allows the users to tailor the PLLs behavior. It is
recommended that ceramic capacitors with NPO or
X7R dielectric be used, since they have very low
effective series resistance. For applications that
require ultra-low, cycle-to-cycle jitter, use the
components shown in Figure 3a. For best total jitter
and best spur reduction, use the components shown
in Figure 3b. Larger values of the pole capacitor (C2)
results in less total jitter; however, the loop stability
decreases. Loop stability decreases since the pole
capacitor begins to dominate over the zero capacitor
(C1). The external loop filter allows the user to change
the loop filter values for specific jitter requirements.
Using a smaller resistor in the loop filter decreases the
PLLs loop bandwidth. This results in less noise from
the PLL input, but potentially more noise from the
VCO.
fphase × Pre Divider × FeedbackDi vider
PreDivider × OutoutDivi der × PostDivide r
fOUT (min) =
14MHz × 2 × 84
2×2×8
fOUT (min) = 73.5MHz
The maximum output frequency
according to the following equation:
fOUT (max) =
is
calculated
18MHz × 2 × 84
2 × 2 ×1
fOUT (max) = 756MHz
Crystal Input and Oscillator Interface
The SY89537L features a fully integrated on-board
oscillator, which minimizes system implementation
cost. The oscillator is a series resonant, multi-vibrator
type crystal driver.
August 2005
Figure 3a. Loop Filter for Lowest
Cycle-to-Cycle Jitter
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Figure 3b. Loop Filter for Lowest Total Jitter and Best
Reference Spur Reduction
The reference spur is located at the phase detector
frequency away from the carrier frequency. The
attenuation of the reference spur is a function of the
loop filter. Figure 4a shows the attenuation of the
reference spur with the loop filter shown in Figure 3a.
Figure 4b shows the attenuation of the reference spur
with the loop filter shown in Figure 3b.
Figure 4b. Reference Spur at -52dB at 16MHz
(R = 130Ω, C1 = 0.47µF, C2 = 1000pF)
Crystal Frequency: 14MHz to 18MHz
Power Supply Filtering Techniques
Mode of Oscillation: Fundamental
Min.
Typ.
Max.
Unit
Frequency Tolerance @25°C
±30
±50
ppm
Frequency Stability over 0*C
to 70°C
±50
±100
ppm
Operating Temperature Range
–20
+70
°C
Storage Temperature Range
–55
+125
°C
Aging (per yr/1 3yrs)
±5
ppm
Equivalent Series Resistance
(ESR)
50
Ω
st
Drive Level
100
As with any high-speed integrated circuit, power
supply filtering is very important. At a minimum,
VCCA, VCCD, and all VCCO pins should be
individually connected using a via to the power supply
plane, and separate bypass capacitors should be
used for each pin. To achieve optimal jitter
performance, each power supply pin should use
separate instances of the circuit shown in Figure 5.
µW
Table 4. Quartz Crystal Oscillator Specifications
Figure 5. SY89537L Recommended
Power Supply De-Coupling
Note:
For VCCA and VCCD use ferrite bead, Murata P/N BLM21A1025.
For VCCO use ferrite bead, Murata, P/N BLM31P005.
Figure 4a. Reference Spur at -39dB at 16MHz
(R = 130Ω, C1 = 0.47µF, C2 = 100pF)
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Synchronization
Output Synchronization Controlled by SYNC Timing Diagram
asserted with a rising edge, the outputs are enabled
when all internal divider stages are reaching their
LOW state. This ensures a simultaneous switching of
all outputs with the next LOW-HIGH transition of the
pre-divider clock.
The SYNC control input is used to synchronize all
divider outputs of the post divider. When a HIGH-LOW
transition is applied to the SYNC control input the
outputs are disabled when all post-divider outputs are
LOW, see “Output Synchronization Controlled by
SYNC Timing Diagram” for details. Once SYNC is
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loop stability in terms of damping factor, natural
frequency, and bandwidth, and illustrates the pole and
zero cutoff frequencies determined by the loop filter
PLL Stability
For the loop filter configurations shown in Figure 3a
and 3b, Table 5a and 5b below summarizes the PLLs
Parameter
VCC
Temperature
VCO Frequency
Charge Pump
Current
Loop Filter
Resistor
Units
3
3
3
3.3
3.3
3.3
3.6
3.6
3.6
V
–40
-40
-40
25
25
25
85
85
85
C
2352
2800
3024
2352
2800
3024
2352
2800
3024
MHz
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
A
130
130
130
130
130
130
130
130
130
Ω
F
Zero Capacitor
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
Pole Capacitor
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
F
VCO Gain
(KVCO)
3.20E+09
4.50E+09
4.50E+09
2.80E+09
3.30E+09
3.10E+09
2.30E+09
1.70E+09
1.30E+09
Hz/V
Feedback Divider
168
168
168
168
168
168
168
168
168
Integer
Phase Detector
Frequency
14
16
18
14
16
18
14
16
18
MHz
Damping Factor
2.6
3.1
3.1
2.4
2.6
2.6
2.2
1.7
1.9
13600.29
16127.95
16127.95
12721.90
13811.16
13386.09
11530.20
9912.83
8668.52
197
160
180
225
219
262
274
424
624
Natural
Frequency
Ratio=Phase
Detector Freq/BW
Hz
Zero Frequency
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
Hz
Loop Bandwidth
(BN)
7.1E+04
9.98E+04
9.98+04
6.21E+04
7.32E+04
6.88E+04
5.1E+04
3.77E+04
2.88E+04
Hz
Pole Frequency
1.22E+07
1.22E+07
1.22E+07
1.22E+07
1.22E+07
1.22E+07
1.22E+07
1.22E+07
1.22E+07
Hz
Table 5a. Optimized for Lowest Cycle-to-Cycle Jitter
(R = 130Ω, C1 = 0.47µF, C2 = 100pF)
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Parameter
VCC
Temperature
VCO Frequency
Charge Pump
Current
Loop Filter
Resistor
Units
3
3
3
3.3
3.3
3.3
3.6
3.6
3.6
V
–40
-40
-40
25
25
25
85
85
85
C
2352
2800
3024
2352
2800
3024
2352
2800
3024
MHz
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
1.80E-04
A
130
130
130
130
130
130
130
130
130
Ω
F
Zero Capacitor
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
4.70E-07
Pole Capacitor
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
1.00E-09
F
VCO Gain
(KVCO)
3.20E+09
4.50E+09
4.50E+09
2.80E+09
3.30E+09
3.10E+09
2.30E+09
1.70E+09
1.30E+09
Hz/V
Feedback Divider
168
168
168
168
168
168
168
168
168
Integer
Phase Detector
Frequency
14
16
18
14
16
18
14
16
18
MHz
Damping Factor
Natural
Frequency
Ratio=Phase
Detector Freq/BW
2.6
3.1
3.1
2.4
2.6
2.6
2.2
1.7
1.9
13600.29
16127.95
16127.95
12721.90
13811.16
13386.09
11530.20
9912.83
8668.52
197
160
180
225
219
262
274
424
624
Hz
Zero Frequency
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
2.61E+03
Hz
Loop Bandwidth
(BN)
7.1E+04
9.98E+04
9.98+04
6.21E+04
7.32E+04
6.88E+04
5.1E+04
3.77E+04
2.88E+04
Hz
Pole Frequency
1.22E+06
1.22E+06
1.22E+06
1.22E+06
1.22E+06
1.22E+06
1.22E+06
1.22E+06
1.22E+06
Hz
Table 5b. Optimized for Total Jitter
(R = 130Ω, C1 = 0.47µF, C2 = 1000pF)
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Figure 6 shows the open and closed loop gain of the
SY89537L. The closed loop-gain plot shows that the
SY89537L when configured with the recommended
loop filter values has essentially no jitter peaking near
the -3dB point. In addition, the open loop curve shows
the frequency at which unity gain occurs for a typical
case of the SY89537L with VCC = 3.3V at TA = 25°C.
At unity gain, Figure 7 can be used to determine the
phase margin or stability of the SY89537L.
dB
Figure 8. VCO Frequency vs.
Loop Filter Control Voltage at 3.3V, TA = 25°C
Frequency (Hz)
Figure 6. Open and Closed Loop Gain
at VCC = 3.3V, TA = 25°C
Figure 9. VCO Gain vs.
Loop Filter Control Voltage at 3.3V, TA = 25°C
Phase Margin (°)
Input Interface
RFCK is designed to accept any differential or singleended input signal 300mV above VCC or 300mV below
GND. RFCK should not be left floating. Tie either the
true or complement input to GND, but not both. A logic
zero is achieved by connecting the complement input
to GND with the true input floating. For TTL input, tie a
2.5kΩ resistor between the complement input and
GND. LVDS, CML and HSTL differential signals may
be connected directly to the reference inputs.
Frequency (Hz)
Figure 7. Phase Margin Plot
at VCC = 3.3V, TA = 25°C
Figure 8 illustrates the VCO frequency versus the loop
filter control voltage at 3.3V, TA = 25°C. The normal
loop filter control voltage is -300mV to +300mV.
Figure 9 illustrates the VCO gain curve at VCC = 3.3V,
TA = 25°C. With this set of information, determining
the loop stability with other sets of loop filter
configurations are possible.
Figure 10. Simplified Input Structure
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Input Termination
Figure 11a. LVPECL Interface
(DC-Coupled)
Figure 11b. LVPECL Interface
(AC-Coupled)
Figure 11c. CML Interface
(DC-Coupled)
Figure 11d. CML Interface
(AC-Coupled)
Figure 11e. LVDS
(DC-Coupled)
Figure 11f. 2.5V LVPECL
(DC-Coupled)
Figure 11g. 2.5V CML
(DC-Coupled)
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Output Bank and Frequency Control
There are five independently programmable output
frequency banks, four differential LVPECL output
banks and one differential LVDS output bank with
three output pairs. Each bank has frequency control
SELx and Enx to generate different divider ratios (see
“PECL and LVDS Output and Frequency Select”
Tables). It can be programmed for pass-through,
internal divided VCO clock divide-by- /2, /8 or disable
state. When disabled, the non-inverted output goes to
static LOW and the inverted output goes to static
HIGH.
Figure 12a. Parallel Thevenin-Equivalent
Output Logic Characteristics
See “Output Termination Recommendations” for
proper termination. When LVPECL single-ended
output is desired, the unused complimentary output
should be terminated. Unused LVPECL output pairs
can be left floating. LVDS output pairs should be
terminated with 100Ω across the pair. In order to
minimize jitter and skew, unused LVDS output banks
and unused LVDS output pairs should be terminated
with 100Ω across each pair.
LVPECL Outputs:
•
Typical voltage swing is 800mV into 50Ω.
•
Common mode voltage is VCCO–1.3V.
Figure 12b. Parallel Termination
LVDS
LVDS specifies a small swing of 325mV typical, on a
nominal 1.2V common mode above ground. The
common mode voltage has tight limits to permit large
variations in ground between an LVDS driver and
receiver. Also, change in common mode voltage, as a
function of data input, is kept to a minimum, to keep
EMI low.
LVDS Outputs:
•
Typical voltage swing is 325mV into 100Ω.
•
Common mode voltage is 1.2V.
Output Termination Recommendations
LVPECL
LVPECL has high input impedance, very low output
(open emitter) impedance, and small signal swing
which results in low EMI. LVPECL is ideal for driving
50Ω-and-100Ω-controlled impedance transmission
lines. There are several techniques for terminating the
LVPECL output: Parallel Termination TheveninEquivalent, Parallel Termination (3-resistor), and ACcoupled termination. Unused output pairs may be left
floating. However, single-ended outputs must be
terminated, or balanced.
Figure 13a. LVDS Differential Measurement
Figure 13b. LVDS Common Mode Measurement
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Related Product and Support Documentation
Part Number
Function
Data Sheet Link
SY89538L
3.3V, Precision LVPECL and LVDS
Programmable, Multiple Output Bank Clock
Synthesizer and Fanout Buffer with Zero Delay
http://www.micrel.com/product-info/products/sy89538l.shtml
HBW Solutions
New Products and Applications
www.micrel.com/product-info/products/solutions.shtml
MLF
August 2005
TM
Application Note
www.amkor.com/products/notes_papers/MLFAppNote.pdf
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SY89537L
Package Information
44-Pin MLF™ (MLF-44)
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http:/www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for
its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a
product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for
surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant
injury to the user. A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk
and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale.
© 2005 Micrel, Incorporated.
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