MICREL SY87724LE

SY87724LE
3.3V AnyRate® MUX/DEMUX Up to 2.7GHz
General Description
Features
The SY87724L is a complete serial data multiplexer and
demultiplexer, capable of operating at up to 2.7GHz. The
device provides for muxing and demuxing to 4, 5, 8, or 10
bit wide buses.
The SY87724L can accept a synchronous code group or
octet boundary input, and uses this input for parallel data
alignment.
The SY87724L is manufactured in Micrel’s high
performance ASSET2™ silicon bipolar process.
Micrel provides a complete protocol transparent solution
with the AnyRate® SY87721L CDR/CMU SY87729L, and
the SY87724L integrated MUX/DEMUX.
Datasheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
• Protocol transparent MUX/DEMUX operation up to
2.7GHz
• Programmable to 4, 5, 8, or 10 bit parallel interfaces
• Differential clock and serial inputs/outputs
• Easily controlled by framer logic
• Synchronous frame boundary indication
• HSPC (High Speed PECL-Compatible) inputs and
outputs
• 3.3V power supply
• Available in 80-pin EPAD-TQFP
Applications
•
•
•
•
•
•
OC-3, OC-12, OC-48, ATM, InfiniBand
Gigabit Ethernet
Fibre Channel, 2X Fibre Channel
SMPTE-259 and 292
Proprietary optical transport
ITU G. 975 Solutions
___________________________________________________________________________________________________________
System Block Diagram
AnyRate and AnyClock are registered trademarks of Micrel, 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
January 2008
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SY87724LE
Ordering Information
Part Number
Package
Type
Operating Range
Package Marking
Lead
Finish
SY87724LEHI
H80-1
Industrial
SY87724LEHI
Sn-Pb
SY87724LEHY
H80-1
Industrial
SY87724LEHY with
Pb-Free bar line indicator
Matte-Sn
Pb-Free
Note:
1. Other Voltage available. Contact Micrel for details.
Pin Configuration
80-Pin EPAD-TQFP (H80-1)
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SY87724LE
Functional Block Diagram
DEMUX
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SY87724LE
MUX
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SY87724LE
Pin Description
previously set boundary, the DPOUTCK± signal will
always occur later than would be expected. That is,
there will never be a short DPOUTCK± pulse.
COMMON
LPBK – TTL Input
This pin defines whether a device exhibits local loopback
or not, as per the following table. Loopback internally
connects MUX serial out to demux serial in, thus the
user may expect MUX side parallel data to appear on
the demux parallel output pins.
LPBK
Functioning
0
Loopback
1
Normal
DP0± through DP4± – Differential PECL Output
These signals may be used as either differential, or
single-ended. When converting to 4 or 5 bits, speed
issues may encourage the use of these signals
differentially. When converting to wider than 5 bits, these
signals are to be used single-ended. Please refer to the
applications section for further details.
DP5 through DP9 – PECL Output
These are the rest of the parallel output bits, to be used
when converting to wider than 5 bits. Which bits are valid
depends on the values of SIZ0, SIZ1, and SIZ2. Please
refer to the table in the applications section for further
details.
Table 1. LPBK Input Pin Function
SIZ0, SIZ1, SIZ2 – TTL Input
These three signals determine the width of the parallel
output, as well as the width of parallel input. The
following table describes the parallel width options.
DPOUTCK± – Differential HSPC Output
This signal is used to strobe the DP0-9 data. It is used
differentially when converting to 4 or 5 bits, and is used
single-ended when converting to wider than 5 bits. The
clock rate of the line will be determined by the DCKIN
signal, and by the setting of the SIZ bits. This output
always provides valid differential logic levels.
(1)
Width
SIZ0
SIZ1
SIZ2
4
0
0
0
5
1
0
0
8
0
1
0
10
1
1
0
Undefined
X
X
1
MUX
Table 2. SIZ0, SIZ1, SIZ2 Input Truth Table
Note:
MP0-9 – PECL Input
These bits accept data for muxing wider than 5 bits.
MPINCK+, used single-ended, determines when this
data may change. Please refer to the table in the
description for which pins represent what bits for various
widths.
1. Pin 8 (SIZ2) should always be tied to a TTL logic level LOW.
DEMUX
DSIN± – Differential HSPC Input
This is the serial input to the SY87724L demux. It
accepts the serial data and converts it to parallel data. It
is ignored during loopback.
MPF0–4± – Differential PECL Input
These signals are used when muxing 4 or 5 bits of
parallel data. MPINCK± determines when this data may
change. Please refer to the MUX table in the description
for which pins represent what bits for various widths.
DCKIN± – Differential HSPC Input
This is the bit rate clock that feeds serial data into the
demux shift register. This signal also feeds the demux
strobe generator and primary divider, except during
loopback.
MTXCLK± – Differential HSPC Input
This is the serial rate clock input to the MUX. It
determines the rate at which serial data will be shifted
out of the MUX.
DFMIN± – Differential HSPC Input
This is the frame alignment input signal. This signal
resets the primary divider, as well as the strobe
generator. This effectively sets the alignment for the
parallel data being demuxed. Usually, DFMIN± asserts
one DCKIN± before a parallel word boundary, and
continues to assert one clock before every boundary.
However, DFMIN± need only occur once for proper
operation. Should DFMIN± assert at other than a
January 2008
MSOUT± – Differential PECL Output
This signal is the serialized data output.
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SY87724LE
OTHER
VCC
Supply Voltage
MPINCK± – Differential PECL Output
This signal indicates when the next set of parallel bits
may be presented to the SY87724L for muxing. For
muxing wider than 5 bits, MPINCK+ is used singleended. These signals always provide valid differential
clock signals regardless of single-ended or differential
data mode.
VCCO
Output Supply Voltage
GND
NC
Ground
These pins are reserved and are to be left
unconnected.
Note:
1. All differential outputs always provide valid differential logic levels
regardless of differential or single-ended use.
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SY87724LE
Description
General
The SY87724L MDM is designed to perform muxing and
demuxing at up to 2.7GHz speeds. The device can
simultaneously MUX and demux up to 10 bits of full duplex
data. In addition, a full parallel-to-parallel loopback function
is implemented, such that parallel data out will loop back to
parallel data in, with the device internally connecting the
serial output to the serial input.
Narrow DeMUX
In this example, serial data is converted into 4 or 5 bit wide
data. Because this can result in very high data rates on the
parallel outputs, they are differential. The DFMIN± input
indicates, synchronously with DCKIN±, and one clock
ahead, the start of a 4 or 5 bit boundary.
Figure 2. Wide DeMUX
As in the narrow case, DPOUTCK± will never assert twice
in 8 or 10 DCKIN± cycles. Should a DFMIN± assertion
change the MDM’s 8 or 10 bit boundary, DPOUTCK±
assertion will be delayed and there will never be a short
assertion.
For 8 bit output, DP4± and DP9 are not used.
The following table summarizes the available bit widths.
The right column shows the parallel bits, in sequence from
first in serially, to last in.
Width
Figure 1. Narrow DeMUX
Every DFMIN± assertion will trigger a new 4 or 5 bit
boundary. Should only one DFMIN± assertion occur, then
DPOUTCK± will continue to assert every 4 or 5 DCKIN±
clocks. Should a subsequent DFMIN± assertion reset the 4
or 5 bit boundary, then DPOUTCK± will always result in a
longer assertion, not a shorter one.
For example, if a subsequent DFMIN± resets a 5 bit
boundary after the second bit in relation to a previous
boundary, then the next DPOUTCK± will always occur 7
DCKIN± later, never 2 DCKIN± later. For four bit output,
DP5± are not used.
Wide DeMUX
The more typical case will be to convert the serial data
stream into 8 or 10 bit wide data. Because the worst case
parallel transfer rate is on the order of 250 to 340 Megatransfers per second, single ended parallel output is
preferred. Thus, only the single-ended side of the
differential outputs is used.
This example is much like the narrow demux, except now
DFMIN± indicates 8 or 10 bit boundaries.
January 2008
Sequence
4
DP0±, DP1±, DP2±, DP3±
5
DP0±, DP1±, DP2±, DP3±, DP4±
8
DP0+, DP1+, DP2+, DP3+, DP5, DP6, DP7, DP8
10
DP0+, DP1+, DP2+, DP3+, DP4+, DP5, DP6, DP7,
DP8, DP9
Table 3. Output Pins for Different Width DeMUX
Narrow MUX
In this scenario, 4 or 5 bit wide parallel data is converted to
a serial bit stream. Because this can result in very high
data rates on the parallel inputs, they are differential. In
this mode of operation, there is no external
synchronization, and the MPINCK± signal pair has
arbitrary phase with respect to the MTXCLK± clock, which
clocks the MUX output shift register.
Figure 3. Narrow MUX
MPINCK± indicates when MDM is ready to accept more
data. It is derived from MTXCLK±, with an arbitrary phase
relationship.
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SY87724LE
Wide MUX
The more typical case will be to convert 8 or 10 bit wide
parallel data words into a serial bit stream. Because the
worst case parallel input rate is on the order of 250 to 340
Mega-transfers per second, single-ended parallel inputs
are used.
This scenario is much like the narrow MUX case, except
now MPINCK+ clocks slower, for 8 or 10 bit parallel words.
small but unspecified time later, at the parallel outputs.
Figure 5. Loopback Function
Figure 4. Wide MUX
Note that the input data indication is now single ended,
and that completely different input pins are used, as
compared to the 4 or 5 bit case.
The following table summarizes the available bit widths.
The right column shows the parallel input bits, such as
they will appear in the serial output stream.
Width
Sequence
4
MPF0±, MPF1±, MPF2±, MPF3±
5
MPF0±, MPF1±, MPF2±, MPF3±, MPF4±
8
MP5, MP6, MP7, MP8, MP0, MP1, MP2, MP3
10
MP5, MP6, MP7, MP8, MP9, MP0, MP1, MP2, MP3,
MP4
Table 4. Output Pins for Different Width MUX
Loopback
To ease system design, the SY87724L MDM has the
capability to loop parallel data in, through the MUX, into
the demux, and back to parallel data out. This permits
system check-out through to the individual MDM device.
Note that, for a full check-out, some form of loopback
further down the serial stream is required.
Loopback is incorporated into MDM by modifying the serial
clock, data, and sync inputs to the demux stage.
During loopback, the source of serial information for the
demux is changed. The MSOUT±, MTXCLK± and
MSYNOUT± are internally muxed to the DSIN±, DCKIN±,
and DFMIN± nodes of the demux section. The
MSYNOUT± signal has the same characteristics as the
DFMIN logic expects.
This exercises the internal data path, both MUX and
demux, for MDM, and also the control logic. The parallel
data presented to the parallel inputs will appear, some
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SY87724LE
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VCC) .......................................–0.5V to +3.8V
(3)
Input Voltage (VIN). ................................... –0.5V to VCC
ECL Output Current (IOUT)
Continuous ...............................................................50mA
Surge ......................................................................100mA
Lead Temperature (soldering, 20sec.) .......................+260°C
Storage Temperature (Ts) ............................. –65°C to 150°C
Supply Voltage (VIN) ................................... +3.15V to +3.45V
Ambient Temperature (TA) ............................ –40°C to +85°C
Junction Thermal Resistance
EPAD-TQFP (θJA) Still-air .................................... 21°C/W
(5)
EPAD-TQFP (θJA) @ 200 LFM ......................... 15°C/W
DC Electrical Characteristics
VCC = VCCA = 3.15V to 3.45V; TA = –40°C to+85°C, unless noted.
Symbol
Parameter
VCC
Power Supply Voltage
ICC
Power Supply Current
Condition
Min
3.15
Typ
Max
Units
3.3
3.45
V
650
750
mA
HSPC DC Electrical Characteristics
VCC = VCCA = 3.15V to 3.45V; TA = –40°C to+85°C, unless noted.
Symbol
Parameter
Max
Units
VIH
Input HIGH Voltage
Condition
VCC–1.165
Min
Typ
VCC–0.880
V
VIL
Input LOW Voltage
VCC–1.810
VCC–1.475
V
IIL
Input LOW Current
VIN = VIL (Min)
–0.5
VOH
Output HIGH Voltage
50Ω to VCC–2V
VCC–1.0
VCC–0.75
V
VOL
Output LOW Voltage
50Ω to VCC–2V
VCC–1.55
VCC–1.25
V
VOSW
Output Voltage Differential Swing
µA
0.3
V
PECL DC Electrical Characteristics
VCC = VCCA = 3.15V to 3.45V; TA = –40°C to+85°C, unless noted.
Symbol
Parameter
Condition
Min
Max
Units
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
VCC–1.165
VCC–0.880
V
VCC–1.810
VCC–1.475
V
IIL
Input LOW Current
VIN = VIL (Min)
–0.5
VOH
Output HIGH Voltage
50Ω to VCC–2V
VCC–1.075
VCC–0.830
V
VOL
Output LOW Voltage
50Ω to VCC–2V
VCC–1.860
VCC–1.570
V
VOSW
Output Voltage Differential Swing
0.6
Typ
µA
V
Notes:
1.
Exceeding the absolute maximum rating may damage the device.
2.
The device is not guaranteed to function outside its operating rating.
3.
The maximum value is specified at VCC up to VCC = +6V.
4.
It is recommended for the part to be used with 200 LFM airflow.
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SY87724LE
TTL DC Electrical Characteristics
VCC = VCCA = 3.15V to 3.45V; TA = –40°C to+85°C, unless noted.
Symbol
Parameter
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
IIH
Input HIGH Current
IIL
Input LOW Current
January 2008
Condition
Min
Typ
Max
2.0
Units
V
0.8
V
VIN = 2.7V, VCC = Max.
+20
µA
VIN = VCC, VCC = Max.
+100
µA
VIN = 0.5V, VCC = Max.
300
µA
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AC Electrical Characteristics
VCC = VCCA = 3.15V to 3.45V; TA = –40°C to+85°C, unless noted.
Symbol
Parameter
Condition
Min
fMAX
Maximum Operating Frequency
2.7
tDCKPWH,
tDCKPWL
Demux Clock Pulse Duty Cycle
45
tDSDS
Demux Serial Data Set-Up
200
ps
tDSDH
Demux Serial Data Hold
0
ps
tDSFS
Demux Serial Frame Set-Up
150
ps
tDSFH
Demux Serial Frame Hold
50
ps
tDPDP
Demux Parallel Differential
Propagation
+200
+800
ps
tDPSP
Demux Parallel Single-Ended
Propagation
+200
+1200
ps
tMCKPWH
tMCKPWL
MUX Clock Pulse Duty Cycle
45
55
%
tMPDS
MUX Parallel Differential Set-Up
tMPDH
MUX Parallel Differential Hold
tMPSS
MUX Parallel Single-Ended Set-Up
(1)
(1)
tMPSH
MUX Parallel Single-Ended Hold
tR, tF
Output Rise/Fall Times
MCKOUT, MSOUT, MSYNOUT
All Others
(1)
(1)
50Ω to VCC–2V (20% to 80%)
Typ
Max
Units
GHz
55
%
tCYC+650
ps
–(tCYC+25
0)
ps
tCYC+850
ps
–(tCYC+50)
ps
100
120
500
ps
Notes:
1.
tCYC = the period of the clock being fed into MTXCLK.
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Timing Waveforms
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Timing Application Example
Notes:
1. MTXCLK = 1Gbps.
2. Time “x” is approximately equal to time “y.”
3. Set-up and hold for MPF0-4± conditional on the MTXCLK± rising edge just prior to the MTXCLK± rising edge that causes an MPINCK± rising edge.
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SY87724LE
Package Information(1)(2)
80-Pin EPAD-TQFP (14 x 14 x 1.0mm) (H80-1)
Notes:
1. Exposed pads must be soldered to a ground plane for proper thermal management.
2. It is recommended for the part to be used with 200 LFM airflow.
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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
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© 2008 Micrel, Incorporated.
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