MICREL SY87739LHYTR

SY87739L
Protocol Transparent, 3.3V,
10MHz to 729MHz, Fractional-N Synthesizer
General Description
Features
The SY87739L is a complete rate independent frequency
synthesizer integrated circuit. From a single reference
source, this device generates a differential PECL output
frequency from 10MHz up to 729MHz
The SY87739L generates an exactly correct reference
frequency for common data transport protocols. This is
especially important in transponder applications, where a
standards compliant protocol data unit must be generated
downstream, even in the absence of any signal from the
associated upstream interface. In addition, the SY87739L
will generate exactly correct reference frequencies for
common data transport protocols augmented by forward
error correction codes. The SY87739L accepts
configuration via a MicroWire™ interface
For proprietary applications, the SY87739L generates
reference frequencies guaranteed to enable the SY87721L
CDR to lock to any possible baud rate from 28Mbps to
2.7Gbps.
Data sheets and support documentation can be found on
Micrel’s web site at: www.micrel.com.
• Protocol transparent fractional-N synthesizer from
10MHz to 729MHz from a single 27MHz reference
oscillator
• Generates exactly the correct frequency for common
transport protocols with or without FEC
• Directly enables SY87721L CDR to lock onto any data
rate within its range
• Exceeds BellCore and ITU jitter generation
specifications
• Programmable via MicroWire™ interface
• Available in 32-Pin ePad-TQFP package
Applications
•
•
•
•
•
Metro access system
Transponders
Bullet item
Multiplexers: access, Add Drop Mux
SONET/SDH/ATM-based transmission systems,
modules and test equipment
• Broadband cross-connects
• Fiber optic test equipment
• Protocols supported: OC-1, OC-3, OC-12, OC-48, ATM,
Gigabit Ethernet, Fast Ethernet, Fibre Channel and 2X
Fibre Channel, 1394, InfiniBand, and Proprietary
Optical Transport
Typical Application Circuit and Typical Performance
AnyClock and AnyRate are registered trademarks of Micrel, Inc.
MicroWire is a trademark of National Semiconductor
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
June 2011
M9999-061511
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Micrel, Inc.
SY87739L
Ordering Information
Part Number
Package Type
Operating Range
Package Marking
Lead Finish
SY87739LHI
H32-2
Industrial
SY87739LHI
Sn-Pb
H32-2
Industrial
SY87739LHI
Sn-Pb
SY87739LHY
H32-2
Industrial
SY87739LHY with Pb-Free Bar Line Indicator
Matte-Sn
Pb-Free
SY87739LHYTR(2, 3)
H32-2
Industrial
SY87739LHY with Pb-Free Bar Line Indicator
Matte-Sn
Pb-Free
SY87739LHITR
(2)
Notes:
1.
Contact factory for die availability. Dice are guaranteed at TA = 25°C, DC electricals only.
2.
Tape and Reel.
3.
Pb-Free package is recommended for new designs.
Pin Configuration
ePad TQFP (H32-2)
Pin Description
Pin Number
Pin Name
1, 24
VCCA
2, 5, 11, 12,
13, 15, 16,
19, 20, 23,
28, 29
NC
Pin Function
Analog Supply (Power). Set to same voltage as VCC.
No Connect. These pins are to be left unconnected.
3, 4
REFCLK±
Reference Clock Input (Differential PECL Input): This is a clock derived from an oscillator or other
sufficiently accurate frequency source. The frequency provided at this input determines, along with
the programming, the output frequency at REFOUT±. Micrel recommends using a 27.000MHz
frequency source.
6
PROGCS
Program Interface Chip Select (TTL Input): This signal forms part of the MicroWire™ interface. When
active high, this signal permits the acquisition of serial data. A falling edge on this input causes
SY87739L to re-acquire lock to a new frequency, based on the program downloaded to it.
June 2011
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SY87739L
Pin Description (Continued)
Pin Number
Pin Name
Pin Function
7
PROGDI
Program Interface Data In (TTL Input): One data bit is sampled on each rising edge of PRGSK, while
PROGCS is active high.
Program Interface Serial Clock (TTL Input): One bit of configuration data is read in each clock cycle.
8
PROGSK
9, 17
VCC
Supply (Power): +3.15V to +3.45V.
10
GND
Ground.
Lock Output (TTL Output): This indicates proper operation of all the blocks in the clock synthesis
chain. Logic high indicates that SY87739L is generating the expected frequency at the CLKOUT±
output. Logic low indicates that one or more PLL in the clock synthesis chain has yet to achieve
proper lock.
14
LOCKED
18
VCCO
21, 22
CLKOUT±
25, 32
GNDA
26, 27
WRVCF±
Wrapper Filter (Analog I/O): These pins connect to the output from the wrapper synthesizer charge
pump, as well as the input to the corresponding VCO. A filter network, as described below, converts
the charge pump current to a voltage, and adjusts loop bandwidth.
FNVCF±
Fractional-N Filter (Analog I/O): These pins connect to the output from the fractional-N synthesizer
charge pump, as well as the input to the corresponding Voltage Controlled Oscillator (VCO). A filter
network, as described below, converts the charge pump current to a voltage, and adjusts loop
bandwidth.
30, 31
June 2011
Output Supply (Power). Set to same voltage as VCC.
Reference Clock Output (Differential PECL Output): This is the synthesized clock generated from
REFCLK±. It can be used to supply a reference clock to a data recovery device, such as Micrel’s
SY87721L.
Analog Ground.
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SY87739L
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VCC).................................... −0.5V to +4.0V
Input Voltage (VIN). ........................................... −0.5V to VCC
ECL Output Current (IOUT)
Continuous............................................................50mA
Surge ..................................................................100mA
Lead Temperature (soldering, 20s) ..................... 260°C
Storage Temperature (Ts) .........................–65°C to +150°C
Supply Voltage (VCC)...........................................+3.3V ±5%
Ambient Temperature (TA) .......................... –40°C to +85°C
Junction Temperature (TJ) ......................................... 125°C
Package Thermal Resistance
ePad TQFP (θJA)(3)
Still-Air......................................................27.6°C/W
500lfpm ....................................................20.7°C/W
DC Electrical Characteristics
VCC = VCCO = VCCA = 3.3V ±5%; GND = GNDA = 0V; TA = –40°C to +85°C.
Symbol
Parameter
Condition
Min.
Typ.
Max.
Units
VCC
Power Supply Voltage
Xxxx
3.15
3.3
3.45
V
ICC
Power Supply Current
210
280
mA
PECL DC Electrical Characteristics
VCC = VCCO = VCCA = 3.3V ±5%; GND = GNDA = 0V; TA = –40°C to +85°C.
Symbol
Parameter
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
IIL
Input LOW Voltage
Condition
Max.
Units
VCC − 1.165
VCC − 1.880
V
VCC − 1.810
VCC − 1.475
V
50ý to VCC −2V
VCC − 1.075
VCC − 1.830
V
50ý to VCC −2V
VCC − 1.860
VCC − 1.570
V
VIN =
Min.
VIL(MIN)(4, 5)
Typ.
−1.5
µA
TTL DC Electrical Characteristics
VCC = VCCO = VCCA = 3.3V ±5%; GND = GNDA = 0V; TA = –40°C to +85°C.
Symbol
Parameter
Condition
Min.
Typ.
Max.
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
VOH
Output HIGH Voltage
IOH = −2mA
VOL
Output LOW Voltage
IOL = 4mA
0.5
V
IIH
Input HIGH Current
VIN = 2.7V, VCC = Maximum
+20
µA
VIN = VCC, VCC = Maximum
+100
IIL
Input LOW Current
VIN = 0.5V, VCC = Maximum
IOS
Output Short-Circuit Current
VOUT = 0V (1s maximum)
2.0
Units
V
0.8
2.0
V
V
µA
−100
−250
mA
Notes:
1.
Permanent device damage may occur if absolute maximum ratings are exceeded. This is 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 rating 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.
Measured with die attach pad soldered to PCB, JEDEC standard multi-layer board.
4.
The REFCLK+ pin has a nominal 75ý pull-down resistor connected to ground.
5.
The REFCLK− pin has a nominal 75ý pull-down resistor connected to ground and a nominal 75ý pull-up resistor connected to VCC.
June 2011
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SY87739L
AC Electrical Characteristics
VCC = VCCO = VCCA = 3.3V ±5%; GND = GNDA = 0V; TA = –40°C to +85°C.
Symbol
Parameter
tIRF
REFCLK Input Rise/Fall Times
tREFPWH
REFCLK Pulse Width High
−
−
ns
tREFPWL
REFCLK Pulse Width Low
−
−
ns
tCSSK
PROGCS-to-PROGSK Preset
−
−
ns
tSKCS
PROGSK-to-PROGCS Recovery
−
−
ns
tSKP
PROGSK Period
−
−
ns
tSKPWH
PROGSK Pulse Width High
−
−
ns
tSKPWL
PROGSK Pulse Width Low
−
−
ns
tDIS
PROGDI Data Setup
−
−
ns
tDIH
PROGDI Data Hold
−
−
ns
CLKOUT Duty Cycle
Condition
tCLKPHW / (tCLKPWH + tCLKPWL)
Typ.
−
−
Max.
Units
ns
−
−
CLKOUT Maximum Frequency
% of UI
−
MHz
−
seconds
Fractional-N VCO Operating
Range
−
MHz
Wrapper VCO Operating Range
−
MHz
Acquisition Lock Time
June 2011
Min.
27MHz Reference Clock
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SY87739L
Timing Waveforms
June 2011
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SY87739L
The bit serial interface conveys 32 bits of configuration
data from a microcontroller to SY87739L. This simple
interface consists of an active high chip select, a serial
clock (2MHz or less) and a serial data input. Each clock
cycle one bit of configuration data transfers to
SY87739L.
Functional Description
General
The SY87739L AnyClock™ Fractional-N Synthesizer is
used in serial data streaming applications, where the
incoming data rate on a channel may vary, or where the
incoming data rate on a channel is unknown ahead of
time.
In these situations, a valid output stream must still be
generated even in the absence of any edges on the
corresponding input stream. Up until now, designers had
to resort to sub-optimal solutions such as providing
multiple reference oscillators. Beyond the potential noise
and EMI issues, the designer has no way to future proof
his circuit, as it would prove near impossible to preprovision all the reference frequencies that might be
needed after deployment, yet are unknown at this time.
The SY87739L solves this problem by generating exact
frequencies for common data streaming protocols, all
from one 27MHz reference. If any of these protocols
include overhead due to use of common digital
wrappers, The SY87739L still generates the exact
frequency required, including the overhead.
Besides generating reference rates for common
protocols directly, the SY87739L also generates
reference frequencies for Micrel’s SY87721L CDR/CMU,
such that it will reliably recover data at any rate between
28Mbps and 2,700Mbps without any gaps.
A simple 3-wire MicroWire™ bit-serial interface loads a
configuration that describes the desired output reference
frequency. All common microcontrollers support this
MicroWire™ interface. Those microcontrollers that don’t
support this interface in hardware can easily emulate the
interface in firmware.
The large set of possible frequencies that the SY87739L
generates, are divided into three classes. First, the sets
of frequencies that match a particular data streaming
protocol are in the “protocol” category. Second, the set
of frequencies that are guaranteed to be near enough to
any arbitrary data rate such that the SY87721L will lock
are in the “picket fence” category. Third, the set of
frequencies that do not fit into either of the first two
categories is in the third category.
The SY87739L generates these important reference
frequencies through two tandem PLL circuits. The first
PLL uses a modified fractional-N approach to generate a
rational ratio frequency. This PLL is capable of
generating all protocol data rates, except for those that
include FEC or digital wrapper overhead. A second,
more traditional P/Q synthesizer optionally adjusts the
output frequency of the first, fractional-N synthesizer, to
accommodate these FEC or digital wrapper data rates.
June 2011
Circuit Description
The heart of SY87739L is its fractional-N synthesizer, as
shown in Figure 1.
Figure 1. Fractional-N Synthesizer Architecture
The two dividers in the feedback path always differ by
one count. That is, if one divider is set to divide by P = 5,
then the other divider divides by P–1 = 4. The mux
chooses between the two based on the control circuit.
The idea behind the fractional-N approach is that every
input reference edge is used. Only those output edges
that are nearest to an input edge get fed back to the
phase-frequency comparator. In addition, the nearest
output edges are chosen in such a way that the net
offset, over a number of edges, zeroes out. It is the
control circuit’s job to drive the mux such that only the
“correct” edges get fed back.
In the above fractional-N circuit, if the output frequency
should be, for example, 5 times the input frequency, then
P is set to 5, and the control circuit sets the mux to only
feed back the output of the P divider.
If the output frequency should be, for example, 41/2
times the input frequency, then the control circuit
alternates evenly between the P and the P–1 divider
output. For every two input edges (one to compare
against P, and another to compare against P–1), you will
get 5 + 4 output edges, yielding an output frequency 9/2
the input frequency.
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SY87739L
Whereas P sets the integer part of the multiplication
factor from input to output frequency, the control circuit
determines the fractional part. By mixing the output of
the P and P–1 dividers correctly, the control circuit can
fashion any output frequency from P–1 times the input to
P times the input, as long as that ratio can be expressed
as a ratio of integers.
During acquisition of the reference, the charge
pump current is fixed at 20µA. Once the
acquisition sequencer has completed center
frequency trimming, then it changes the current
of this charge pump to 50µA.
Fractional-N VCO
This circuit converts the voltage integrated by the
external loop filter into a digital clock stream. The
frequency of this clock varies based on this control
voltage. This VCO has a coarse and a fine input, with a
combined range of 540MHz to 729MHz. The coarse
input trims the VCO, as described below, so that its
center frequency rests near the target frequency to
generate. The fine adjustment forms part of the closed
loop. VCO gain is nominally 200MHz per volt.
Fractional-N P/P-1 Divider
This is the main divider for the fractional-N loop. The
logical value of the output of the control block (Figure 1)
defines whether the divider divides by P (values shown
in Table 1) or by P–1. The expression for the fractional
division becomes:
Figure 2. 11/3 Example
Figure 2 shows an example generating an output
frequency 3 2/3 times the input frequency. Since the
output frequency is between 3 and 4 times the input, P is
set to 4. We need to select the P divider twice, and
select the P–1 divider once. Multiplying by 4 two times
out of three, and multiplying by 3 one time out of three,
averages to a multiplication of 32/3.
The top waveform is the reference input. The bottom
waveform is the multiplied output. The waveform in the
middle shows those edges from the output that most
closely matches a corresponding reference waveform
edge.
The control circuit must generate a repeating pattern to
the mux of something like “101”, so that the P divider is
selected twice, and the P–1 divider is selected once,
every three reference edges.
⎡
⎤
Q P−1
Fractional Division = P − ⎢
⎥
(
)
+
Q
Q
P ⎦
⎣ P −1
Where QP is the number of reference clock periods
during which the divider must divide by P and QP-1 is the
number of reference clock periods during which the
divider must divide by P–1.
Care should be exercised when selecting the value of P
(Table 1) so that the voltage-controlled oscillator (VCO)
of the fractional-N PLL is not driven out of range. The
following conditions must be met:
fVCO(MIN) < fREF × Fractional Division < fVCO(MAX)
Fractional-N Phase-Frequency Detector
This circuit, besides generating “pump up” and “pump
down” signals, also generates delta phase signals for
use by the lock detect circuit.
This detector circuit also accepts a gating signal from the
fractional-N control block. When gated, the phase
detector generates neither pump up nor pump down
pulses.
or
⎧⎪
⎡
QP − 1
fVCO(MIN) < fREF × ⎨P − ⎢
⎪⎩
⎣⎢ Q P − 1 + Q P
(
Fractional-N Charge Pump
This circuit converts the “pump up” and “pump down”
signals from the phase-frequency detector into current
pulses. An external loop filter integrates these current
pulses into a control voltage.
Charge pump current is selectable. This modifies loop
gain as follows:
June 2011
)
⎤ ⎫⎪
⎥ ⎬ < fVCO(MAX)
⎦⎥ ⎪⎭
where:
fVCO(MIN) = 540MHz
fVCO(MAX) = 729MHz
fREF = Frequency of the reference clock
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SY87739L
DivSel3
DivSel2
DivSel1
DivSel0
P
0
0
0
0
17
0
0
0
1
18
0
0
1
0
19
0
0
1
1
20
0
1
0
0
21
0
1
0
1
22
0
1
1
0
23
0
1
1
1
24
1
0
0
0
25
1
0
0
1
26
1
0
1
0
27
1
0
1
1
28
1
1
0
0
29
1
1
0
1
30
1
1
1
0
31
1
1
1
1
32
In Figure 2, we multiply by 11/3, or 41/3. Matching
against the formula, P = 4, QP–1 = 1, and QP =2.
The SY87739L accepts QP and QP–1 values from its
MicroWire™ interface, where they exist as the 5-bit
values “qp” and “qpm1.” Both values are unsigned binary
numbers. QP and QP-1 are both constrained to be 31 or
less, and their sum is also constrained to be 31 or less.
That means that the denominator in the above formula
must be 31 or less.
As would be expected from the formula, setting QP to
zero causes frequency multiplication exactly by P–1.
Setting QP–1 to zero causes frequency multiplication
exactly by P. The SY87739L behavior is undefined if
both QP and QP–1 are both set to zero.
In the general case, the length of the repeating binary bit
pattern is QP + QP–1. It consists of QP “1”, and QP–1 “0.”
The SY87739L accomplishes this by implementing
Bresenham’s algorithm in hardware. To see how this
works, we need a more complicated example. Let’s say
we need to multiply by 110/23, or 5 – 5/23. In this
example, P = 5, QP–1 = 5, and QP = 18. The naïve
approach would generate a bit pattern of:
Table 1. DivSel Divider Setting
Fractional-N Control
This circuit controls the P/P–1 divider, selecting the
appropriate divide ratio, either P or P–1, in the correct
pattern.
As explained in the example of Figure 2 above,
controlling the P/P–1 divider amounts to generating a
repeating binary bit stream. In that example, a “1”
represents dividing by 4, and a “0” represents dividing by
3. The full cycle, “101”, says to divide by 4 twice, and to
divide by 3 once.
In the general case, the pattern “101” need not change
based on the P divider value. To multiply by 14/3 instead
of 11/3, for example, the same “101” pattern would be
used, but we would alternate dividing by 5 and 4, instead
of dividing by 4 and 3. The P value, in effect, represents
the integer part of the multiplication factor.
The repeating binary bit pattern really depends only on
the number of times to divide by P, and the number of
times to divide by P–1. We label the number of times to
divide by P as QP, and the number of times to divide by
P–1 as QP–1. The fractional-N synthesizer generates its
output frequency as per this formula:
11111 11111 11111 11100 000
The spaces between groups of five digits are added for
readability only. This pattern is 23 bits long, with QP (that
is, 18) “1” and QP–1 (that is, 5) “0”, so it will multiply
correctly, but it doesn’t match P/P–1 divider edges to
input edges in the best way possible.
In fact, the best pattern, in terms of minimizing distance
between divider and reference input edges, is:
11110 11110 1110 11110 1110
Table 2 shows how Bresenham’s algorithm works. The
first column is an accumulator. It starts at zero, but
otherwise takes the result from the fourth column of the
previous row. The second column is the value to add to
the accumulator at each step. In the general case, this is
always QP–1. The third column forms the sum. The fourth
column takes the sum modulo (QP + QP–1).
The last column is “0” whenever the modulo changes the
sum. Note that the Table has 23 rows, before the sum is
zero, and the entire algorithm repeats itself.
⎡
QP − 1 ⎤
fFNOUT = ⎢P −
⎥ × fREF
Q P + Q P − 1 ⎥⎦
⎢⎣
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SY87739L
Accum
Add
Sum
Modulo
Bit
0
5
5
5
1
5
5
10
10
1
10
5
15
15
1
15
5
20
20
1
20
5
25
2
0
2
5
7
7
1
7
5
12
12
1
12
5
17
17
1
17
5
22
22
1
22
5
27
4
0
4
5
9
9
1
9
5
14
14
1
14
5
19
19
1
19
5
24
1
0
1
5
6
6
1
6
5
11
11
1
11
5
16
16
1
16
5
21
21
1
21
5
26
3
0
3
5
8
8
1
8
5
13
13
1
13
5
18
18
1
18
5
23
0
0
An 8-bit counter implements the voltage steps. The
acquisition sequencer steps through this counter, which
changes its voltage by about 12mV per step. The coarse
input to the VCO is nominally set at 500MHz per volt.
The acquisition sequencer exercises the center
frequency trim circuit so that the VCO control voltage
ends up within about 12mV of where it should be, were it
exactly centered for the desired output frequency.
Lock Detector
The SY87739L ensures proper operation of both
synthesizers by verifying that both PLL have achieved
lock. The LOCKED output asserts active high only when
this is the case, that is, both PLL are locked.
The SY87739L implements a digital lock detector that is
both simple and robust. Each phase-frequency detector
provides a charge pump output that is the logical OR of
pump up and pump down pulses.
The lock-detect circuit processes this charge pump
output with a pulse width discriminator. Once each
reference clock rising edge, the discriminator will
produce a pulse, only if the phase difference between
the feedback divider and the reference input is too large.
These pulses are subsequently processed digitally. A
PLL that is out of lock, is declared to be in lock only if
256 consecutive reference clocks have NO large phase
errors, as reported by the pulse width discriminator. Any
large phase error event, even a single one, that arrives
before lock is declared, will reset the circuit.
Once in lock, a PLL is declared out of lock if more
large-phase-difference
than
small-phase-difference
events occur that is, if over time, a net of 256 largephase-difference events occur. That is accomplished by
counting up when large-phase-difference events occur
and counting down in the case of small-phase events.
Table 2. 5/23 Example
Note that the sequence of bits in the last column,
reading down, is the optimal pattern to generate.
The choice of repeating bit pattern reduces jitter
because a fractional-N synthesizer relies on edges
temporarily not matching, but averaging out over some
time interval. Anything that reduces the timing disparity
between edges arriving at the phase-frequency
comparator will reduce jitter.
Wrapper Synthesizer
The frequency generated by the fractional-N PLL is
further processed by a more classical PLL circuit, as
shown in Figure 3.
Center Frequency Trim
This circuit block generates two identical reference
voltages for the two VCO on the SY87739L. This voltage
pair can be digitally trimmed. Trimming occurs under
control of the acquisition sequencer, which trims for
center frequency of the fractional-N synthesizer only.
The wrapper synthesizer VCO is matched to the
fractional-N VCO. Both VCO are fed the same coarse
adjustment voltage, and so both center nominally at the
same frequency.
June 2011
Figure 3. Wrapper Architecture
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SY87739L
The divisors are in two sets. The first set consists of the
divisors 14, 15, 16, 17, and 18. The second set consists
of 31 and 32. Both M and N must be chosen from the
same set. For example, an N divisor of 31 and an M
divisor of 17 results in undefined behavior. The
17
18
⎛N⎞
, that is
is
⎜ ⎟ ratio must be kept smaller than
14
14
⎝M⎠
not allowed.
This circuit further modifies the frequency generated by
the fractional-N loop. This comes in handy where digital
frequency and/or FEC is implemented. The wrapper
synthesizer generates just a few ratios near 1.
The wrapper modifies the frequency based on the values
of M and N, the dividers, as per:
540MHz ≤ fWROUT =
Q P −1 ⎤
N
N ⎡
× fFNOUT = × ⎢P −
⎥
Q P −1 + Q P ⎦
M
M ⎣
Wrapper N Divider
This circuit forms the numerator of the ratio by which the
wrapper synthesizer modifies the fractional-N output
frequency. The division ratio is selected via MicroWire™,
wrapper and/or FEC is implemented. The wrapper as the
3-bit NdivSel register, as per Table 4.
× fREF ≤ 729MHz
Wrapper Phase-Frequency Detector
This circuit generates pump up and pump down signals
for the charge pump, and also generates delta phase for
the lock detector.
NdivSel2
NdivSel1
NdivSel0
Divisor
Wrapper Charge Pump
This circuit converts the pump signals from the phasefrequency detector into current pulses. Charge pump
current is fixed at about 20µA. An external loop filter
integrates these current pulses into a control voltage.
0
0
0
16
0
0
1
16
0
1
0
18
0
1
1
17
1
0
0
31
Wrapper VCO
This circuit matches the fractional-N VCO in construction
and operation, so that the center frequency trim circuit
can center both the fractional-N VCO and the wrapper
VCO at about the same frequency.
1
0
1
14
1
1
0
32
1
1
1
15
Table 4. NdivSel Divisor Control
Wrapper M Divider
This circuit forms the denominator of the ratio by which
the wrapper synthesizer modifies the fractional-N output
frequency. The division ratio is selected via MicroWire™,
as the 3-bit MdivSel register, as per Table 3.
MdivSel2
MdivSel1
MdivSel0
Divisor
0
0
0
16
0
0
1
16
0
1
0
18
0
1
1
17
1
0
0
31
1
0
1
14
1
1
0
32
1
1
1
15
The output of the wrapper synthesizer is post divided
down before appearing at the CLKOUT± pins. Notice
that, given the range of the wrapper VCO (540MHz to
729MHz) and the maximum and minimum division ratios
of the P divider (1 to 60, as shown in Table 5), the
minimum and maximum frequency of CLKOUT± is
10MHz and 729MHz respectively.
Table 3. MdivSel Divisor Control
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SY87739L
PostDivSel Bit
MicroWire™ Interface
This standard bit-serial interface eases interfacing the
SY87739L to microcontrollers. The SY87739L accepts
one data bit on PROGDI per rising edge on PROGSK.
The data is ignored when PROGCS is inactive low.
When PROGCS is active high, bits are shifted into the
SY87739L. The falling edge of PROGCS then initiates
acquisition of the output frequency defined by the 32-bit
program just loaded into the SY87739L.
This means that, if the user wishes to re-acquire based
on the same program, PROGCS needs to toggle high
then low.
Divisor
4
3
2
1
0
0
0
0
0
0
1
0
0
0
0
1
3
0
0
0
1
0
2
0
0
0
1
1
3
0
0
1
0
0
4
0
0
1
0
1
5
0
0
1
1
0
6
0
0
1
1
1
7
0
1
0
0
0
8
0
1
0
0
1
9
0
1
0
1
0
10
0
1
0
1
1
11
0
1
1
0
0
12
0
1
1
0
1
13
0
1
1
1
0
14
0
1
1
1
1
15
1
0
0
0
0
16
1
0
0
0
1
18
1
0
0
1
0
20
1
0
0
1
1
22
1
0
1
0
0
24
1
0
1
0
1
26
1
0
1
1
0
28
1
0
1
1
1
30
1
1
0
0
0
32
1
1
0
0
1
36
1
1
0
1
0
40
1
1
0
1
1
44
1
1
1
0
0
48
1
1
1
0
1
52
1
1
1
1
0
56
1
1
1
1
1
60
Programming
To program the SY87739L to generate a certain
frequency:
1. Determine the required values of the programming
parameters, as summarized in Table 6.
2. Set PROGCS active high.
3. Shift in each of the 32 bits, as per Table 6. The fields
are loaded in sequence, from the first row to the last
row. For each multi-bit field, the most significant bit
is shifted in first. Shift the bits in through PROGDI,
clocking them with PROGSK edges.
4. Set PROGCS inactive low.
5. Wait for LOCKED to assert high.
# Bits
Reference
4
Always “000”
qp
5
Section: Gating the P/P-1Divider
qpm1
5
Section: Gating the P/P-1Divider
divsel
4
Table 1
Mfg.
3
Always “000”
PostDivSel
5
Table 5
NdivSel
3
Table 4
MdivSel
3
Table 3
Table 6. Programming Sequence
Table 5. Setting to Program the Division Ratio of the P
Divider
The SY87739L generates exact frequencies for common
serial data streaming protocols. Summary programming
information appears in the next section. The SY87739L
also enables Micrel’s SY87721L AnyRate™ CDR to
decode virtually anything within its range of operation, all
from a 27.000MHz reference. Details about how to
program the SY87739L in the general case, including
derivation of programs for both the standard protocols
and the AnyRate™ application, appear in an applications
note.
The divisor value is selected via MicroWire™. The 5-bit
PostDivSel register determines the divisor value. It is set
as per Table 5. The SY87739L does not guarantee a
50% duty cycle output. It is designed to provide well
timed rising edges only.
June 2011
Field
Preamble
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SY87739L
Standard Protocol Applications
From a single 27.000MHz reference input, the
SY87739L can generate exactly correct frequencies for
at least the 18 wrapper, then modify the NdivSel and
MdivSel bits protocols listed in Table 7. This table also
shows how to program the SY87739L for each protocol
listed. This table assumes no digital wrapper. If your
system includes such a can generate exactly correct
frequencies for at least the 18 wrapper, then modify the
NdivSel and MdivSel bits accordingly.
Figure 4. Recommended Loop Filter Values
Loop Filter Values
Each PLL in the SY87739L adjusts its loop gain through
an external loop filter. Figure 4 shows Micrel’s
recommended values for these.
Protocol
SY87739L FOUT (MHz)
Programming Bits
ETR
32
0000 10011 01000 0111 000 10010 101 101
OC-1
51.84
0000 00001 11000 0111 000 01100 101 101
Fast Ethernet
50
0000 00010 11001 1000 000 01101 101 101
FDDI
125
0000 00100 10111 0111 000 00101 101 101
1/8 Fibre Channel
13.28125
0000 01011 00111 0111 000 11100 101 101
General
150
0000 00010 00111 0110 000 00100 101 101
OC-3/STM-1
155.52
0000 00001 11000 0111 000 00100 101 101
ESCON
50
0000 00010 11001 1000 000 01101 101 101
1/4 Fibre Channel
26.5625
0000 01011 00111 0111 000 10100 101 101
1/2 Fibre Channel
53.125
0000 01011 00111 0111 000 01100 101 101
OC-12/STM-4
622.08
0000 00011 11000 0111 000 00000 101 101
Fibre Channel
106.25
0000 01011 00111 0111 000 00110 101 101
Gigabit Ethernet
156.25
0000 00100 10111 0111 000 00100 101 101
D1 Video
69
0000 00001 00000 0110 000 01001 101 101
HDTV
92.8125
0000 00001 01111 1000 000 00111 101 101
Infiniband
125
0000 00100 10111 0111 000 00100 101 101
2x Fibre Channel
212.5
0000 01011 00111 0111 000 00011 101 101
OC-48/STM-16
155.52
0000 00001 11000 0111 000 00100 101 101
OC-48/STM-16
622
0000 00001 11000 0111 000 00000 101 101
Table 7. Protocol Listings
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SY87739L
System Block Diagram
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SY87739L
Functional Block Diagram
Related Product and Support Documentation
Part Number
Function
Data Sheet Link
SY87739L-EVAL
Fractional-N Synthesizer Evaluation Board
www.micrel.com/product-info/eval_boards.shtml
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SY87739L
Package Information
PCB Thermal Consideration for 32-Pin ePad TQFP Package
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SY87739L
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
Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this data sheet. This
information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry,
specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual
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relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
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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.
© 2006 Micrel, Incorporated.
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