MICREL SY89840UMGTR

SY89840U
Precision LVPECL Runt Pulse Eliminator 2:1
Multiplexer
General Description
The SY89840U is a low jitter PECL, 2:1 differential input
multiplexer (MUX) optimized for redundant source
switchover applications. Unlike standard multiplexers,
the SY89840U unique 2:1 Runt Pulse Eliminator (RPE)
MUX prevents any short cycles or “runt” pulses during
switchover. In addition, a unique Fail-Safe Input
protection prevents metastable conditions when the
selected input clock fails to a DC voltage (voltage
between the pins of the differential input drops below
100mV).
The differential input includes Micrel’s unique, 3-pin
input termination architecture that allows customers to
interface to any differential signal (AC or DC-coupled) as
small as 100mV (200mVpp) without any level shifting or
termination resistor networks in the signal path. The
output is 800mV, 100K compatible LVPECL with fast
rise/fall times guaranteed to be less than 190ps.
The SY89840U operates from a 2.5V ±5% or 3.3V
±10% supply and is guaranteed over the full industrial
temperature range of –40°C to +85°C. The SY89840U is
®
part of Micrel’s high-speed, Precision Edge product
line. All support documentation can be found on Micrel’s
web site at: www.micrel.com.
Precision Edge
®
Features
• Selects between two sources, and provides a glitch-free,
stable LVPECL output
• Guaranteed AC performance over temperature and supply
voltage:
– Wide operating frequency: 1kHz to >1.5GHz
– < 880ps In-to-Out tpd
– < 190ps tr/tf
• Unique patent-pending input isolation design minimizes
crosstalk
• Fail-safe input prevents oscillations
• Ultra-low jitter design:
– <1psrms random jitter
– <1psrms cycle-to-cycle jitter
– <10pspp total jitter (clock)
– <0.7psrms MUX crosstalk induced jitter
• Unique patent-pending input termination and VT pin
accepts DC-coupled and AC-coupled inputs (CML,
PECL, LVDS)
• 800mV LVPECL output swing
• 2.5V ±5% or 3.3V ±10% supply voltage
• –40°C to +85°C industrial temperature range
• Available in 16-pin (3mm x 3mm) QFN package
Applications
• Redundant clock switchover
• Failsafe clock protection
Markets
•
•
•
•
LAN/WAN
Enterprise servers
ATE
Test and measurement
Precision Edge is a registered trademark 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
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SY89840U
Typical Application
Simplified Example Illustrating RPE (Runt Pulse Elimination)
Circuit when Primary Clock Fails
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Ordering Information(1)
Part Number
Package Type
Operating Range
Package Marking
Lead Finish
SY89840UMG
QFN-16
Industrial
840U with bar-line
Pb-Free indicator
NiPdAu
Pb-Free
SY89840UMGTR(2)
QFN-16
Industrial
840U with bar-line
Pb-Free indicator
NiPdAu
Pb-Free
Notes:
1. Contact factory for die availability. Dice are guaranteed at TA = 25°C, DC Electricals Only.
2. Tape and Reel.
Pin Configuration
16-Pin QFN
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Pin Description
Pin Number
Pin Name
4, 1,
IN0, /IN0,
16, 13
IN1, /IN1
3, 15
2, 14
VT0, VT1
VREF-AC0
VREF-AC1
Pin Function
Differential Inputs: These input pairs are the differential signal inputs to the
device. These inputs accept AC or DC-coupled signals as small as 100mV
(200mVpp). Each pin of a pair internally terminates to a VT pin through 50Ω.
Please refer to the “Input Interface Applications” section for more details.
Input Termination Center-Tap: Each side of the differential input pair terminates
to a VT pin. The VT0 and VT1 pins provide a center-tap to a termination network
for maximum interface flexibility. See the “Input Interface Applications” section for
more details.
Reference Voltage: This output biases to VCC–1.2V. It is used for AC-coupling
inputs IN and /IN. Connect VREF-AC directly to the corresponding VT pin. Bypass
with 0.01µF low ESR capacitor to VCC. Maximum sink/source current is ±1.5mA.
Due to the limited drive capability, the VREF-AC pin is only intended to drive its
respective VT pin. See “Input Interface Applications” section.
10
SEL
This single-ended TTL/CMOS-compatible input selects the inputs to the
multiplexer. Note that this input is internally connected to a 25kΩ pull-up resistor
and will default to a logic HIGH state if left open.
5, 8, 12
VCC
Positive Power Supply: Bypass with 0.1µF//0.01µF low ESR capacitors as close
to VCC pins as possible.
6, 7
Q, /Q
Differential Outputs: This differential LVPECL output is a logic function of the IN0,
IN1, and SEL inputs. Please refer to the truth table below for details.
9
GND
Exposed Pad
11
CAP
Ground: Ground pin and exposed pad must be connected to the same ground
plane.
Power-On Reset (POR) Initialization capacitor. When using the multiplexer with
RPE capability, this pin is tied to a capacitor to VCC. The purpose is to ensure the
internal RPE logic starts up in a known state. See "Power-On Reset (POR)
Description" section for more details regarding capacitor selection. If this pin is
tied directly to VCC, the RPE function will be disabled and the multiplexer will
function as a normal multiplexer. The CAP pin should never be left open.
Truth Table
February 2005
IN0
/IN0
INPUTS
IN1
/IN1
SEL
0
1
X
X
0
0
1
1
0
X
X
0
1
0
X
X
0
1
1
0
1
X
X
1
0
1
1
0
4
OUTPUTS
Q
/Q
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Absolute Maximum Ratings(1)
Storage Temperature (Ts).................................... –65°C to 150°C
Operating Ratings(2)
Supply Voltage (VCC) .............................................. –0.5V to +4.0V
Input Voltage (VIN) ......................................................–0.5V to VCC
Supply Voltage (VCC) .............................+2.375V to +2.625V
.............................................................. +3.0V to +3.6V
Ambient Temperature (TA)........................... –40°C to +85°C
Package Thermal Resistance(3)
QFN (θJA)
Still-Air ............................................................... 60°C/W
QFN (ΨJB)
Junction-to-Board .............................................. 33°C/W
LVPECL Output Current (IOUT)
Continuous ......................................................... ±50mA
Surge................................................................ ±100mA
Termination Current
Source/Sink Current on VT ........................................ ±100mA
Source/Sink Current on IN, /IN.................................... ±50mA
VREF-AC Current
Source/sink current on VREF-AC ...................................... ±2mA
Lead Temperature (soldering, 20 sec.) ..............................+260°C
DC Electrical Characteristics(4)
TA = –40°C to +85°C; unless otherwise stated.
Symbol
Parameter
VCC
Power Supply
Condition
Max
Units
2.375
Min
2.625
V
3.0
3.6
V
No load, max VCC.
Typ
ICC
Power Supply Current
65
95
mA
RIN
Input Resistance
(IN-to-VT)
45
50
55
Ω
RDIFF_IN
Differential Input Resistance
(IN-to-/IN)
90
100
110
Ω
VIH
Input High Voltage
(IN, /IN)
1.2
VCC
V
VIL
Input Low Voltage
(IN, /IN)
0
VIH–0.1
V
VIN
Input Voltage Swing
(IN, /IN)
See Figure 1a. Note 5
0.1
VCC
V
VDIFF_IN
Differential Input Voltage Swing
|IN-/IN|
See Figure 1b.
0.2
VIN_FSI
Input Voltage Threshold that Triggers
FSI
VT_IN
IN-to-VT
(IN, /IN)
VREF-AC
Output Reference Voltage
V
30
VCC–1.3
VCC–1.2
100
mV
1.28
V
VCC–1.1
V
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 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. 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. VIN (max) is specified when VT is floating.
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LVPECL Outputs DC Electrical Characteristics(6)
VCC = 2.5V ±5% or 3.3V ±10%; TA = -40°C to + 85°C; RL = 50Ω to VCC-2V, unless otherwise stated.
Symbol
Parameter
VOH
Output HIGH Voltage
Q, /Q
Condition
VCC-1.145
Min
Typ
VCC–0.895
Max
Units
V
VOL
Output Low Voltage
Q, /Q
VCC-1.945
VCC–1.695
V
VOUT
Output Voltage Swing
Q, /Q
See Figure 1a
550
800
mV
VDIFF-OUT
Differential Output Voltage Swing
Q, /Q
See Figure 1b
1100
1600
mV
LVTTL/CMOS DC Electrical Characteristics(6)
VCC = 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
-125
IIL
Input LOW Current
-300
Typ
Max
2.0
Units
V
0.8
V
30
µA
µA
Note:
6.
The circuit is designed to meet the DC specifications shown in the above table after thermal equilibrium has been established.
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AC Electrical Characteristics(7)
VCC = 2.5V ±5% or 3.3V ±10%; TA = –40°C to + 85°C, RL = 50Ω to VCC–2V, unless otherwise stated.
Symbol
Parameter
Condition
Min
Typ
Max
Units
fMAX
Maximum Operating Frequency
Clock
1.5
2.0
tpd
Differential Propagation Delay In-to-Q
100mV < VIN ≤ 200mV(8)
480
625
880
ps
In-to-Q
(8)
460
600
820
ps
17
cycles
900
ps
RPE enabled, see Timing Diagram
SEL-to-Q
RPE disabled (VIN = VCC/2)
tpd
Tempco
Differential Propagation Delay
Temperature Coefficient
tSKEW
Part-to-Part Skew
550
o
fs/ C
115
Note 9
200
ps
Random Jitter
Note 10
1
ps(rms)
Cycle-to-Cycle Jitter
Note 11
1
ps(rms)
Total Jitter (TJ)
Note 12
10
ps(pp)
0.7
ps(rms)
190
ps
tJitter
tr, tf
200mV < VIN ≤ 800mV
SEL-to-Q
GHz
Crosstalk-induced Jitter
Note 13
Output Rise/Fall Time (20% to 80%)
At full output swing
70
130
Notes:
7.
High-frequency AC-parameters are guaranteed by design and characterization.
8.
Propagation delay is measured with input tr, tf ≤ 300ps (20% to 80%) and VIL ≥ 800mV.
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. Random jitter is measured with a K28.7 character pattern, measured at <fMAX.
11. 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.
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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Functional Description
RPE MUX and Fail-Safe Input
The SY89840U is optimized for clock switchover
applications where switching from one clock to
another clock without runt pulses (short cycles) is
required. It features two unique circuits:
Runt-Pulse Eliminator (RPE) Circuit:
The RPE MUX provides a “glitchless” switchover
between two clocks and prevents any runt pulses
from occurring during the switchover transition. The
design of both clock inputs is identical (i.e., the
switchover sequence and protection is symmetrical
for both input pair, IN0 or IN1. Thus, either input pair
may be defined as the primary input). If not required,
the RPE function can be permanently disabled to
allow the switchover between inputs to occur
immediately. If the CAP pin is tied directly to VCC,
the RPE function will be disabled and the multiplexer
will function as a normal multiplexer.
Fail-Safe Input (FSI) Circuit:
The FSI function provides protection against a
selected input pair that drops below the minimum
amplitude requirement. If the selected input pair
drops sufficiently below the 100mV minimum singleended input amplitude limit (VIN), or 200mV
differentially (VDIFF_IN), the output will latch to the last
valid clock state.
RPE and FSI Functionality
The basic operation of the RPE MUX and FSI
functionality is described with the following four case
descriptions. All descriptions are related to the true
inputs and outputs. The primary (or selected) clock
is called CLK1; the secondary (or alternate) clock is
called CLK2. Due to the totally asynchronous
relation of the IN and SEL signals and an additional
internal protection against metastability, the number
of pulses required for the operations described in
cases 1-4 can vary within certain limits. Refer to
“Timing Diagrams” for more detailed information.
Case #1 Two Normal Clocks and RPE Enabled
In this case the frequency difference between the
two running clocks IN0 and IN1 must not be greater
than 1.5:1. For example, if the IN0 clock is 500MHz,
the IN1 clock must be within the range of 334MHz to
750MHz.
If the SEL input changes state to select the alternate
clock, the switchover from CLK1 to CLK2 will occur
in three stages.
•
•
•
Stage 1: The output will continue to follow CLK1 for
a limited number of pulses.
Stage 2: The output will remain LOW for a limited
number of pulses of CLK2.
Stage 3: The output follows CLK2.
Timing Diagram 1
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Case #2 Input Clock Failure: Switching from a
selected clock stuck HIGH to a valid clock (RPE
enabled).
If CLK1 fails HIGH before the RPE MUX selects
CLK2 (using the SEL pin), the switchover will occur
in three stages.
•
•
•
Stage 1: The output will remain HIGH for a limited
number of pulses of CLK2.
Stage 2: The output will switch to LOW and then
remain LOW for a limited number of falling edges of
CLK2.
Stage 3: The output will follow CLK2
Timing Diagram 2
Note:
Output shows extended clock cycle during switchover. Pulse width for both high and low of this cycle will always be greater than 50% of
the CLK2 period.
Case #3 Input Clock Failure: Switching from a
selected clock stuck Low to a valid clock (RPE
enabled).
If CLK1 fails LOW before the RPE MUX selects
CLK2 (using the SEL pin), the switchover will occur
in two stages.
•
•
Stage 1: The output will remain LOW for a limited
number of falling edges of CLK2.
Stage 2: The output will follow CLK2.
Timing Diagram 3
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Case #4 Input Clock Failure: Switching from the
selected clock input stuck in an undetermined state
to a valid clock input (RPE enabled).
If CLK1 fails to an undetermined state (e.g.,
amplitude falls below the 100mV (VIN) minimum
single-ended input limit, or 200mV differentially)
before the RPE MUX selects CLK2 (using the SEL
pin), the switchover to the valid clock CLK2 will
occur either following Case #2 or Case #3,
depending on the last valid state at the CLK1.
If the selected input clock fails to a floating, static, or
extremely low signal swing, including 0mV, the FSI
function will eliminate any metastable condition and
guarantee a stable output signal. No ringing and no
undetermined state will occur at the output under
these conditions.
Please note that the FSI function will not prevent
duty cycle distortions or runt pulses in case of a
slowly deteriorating (but still toggling) input signal.
Due to the FSI function, the propagation delay will
depend on rise and fall time of the input signal and
on its amplitude. Refer to “Typical Operating
Characteristics” for more detailed information.
Timing Diagram 4
Power-On Reset (POR) Description
The SY89840U includes an internal power-on reset
(POR) function to ensure the RPE logic starts-up in
a known logic state once the power-supply voltage is
stable. An external capacitor connected between
VCC and the CAP pin (pin 11) controls the delay for
the power-on reset function.
Calculation of the required capacitor value is based
on the time the system power supply needs to power
up to a minimum of 2.3V. The time constant for the
internal power-on-reset must be greater than the
time required for the power supply to ramp up to a
minimum of 2.3V.
The following equation describes this relationship:
C(μF) ≥
t dPS ( ms )
12( ms / μF )
As an example, if the time required for the system
power supply to power up past 2.3V is 12ms, the
required capacitor value on pin 11 would be:
C(μF) ≥
12ms
12( ms / μF )
C(μF) ≥ 1μF
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Typical Operating Characteristics
VCC = 3.3V, GND = 0V, VIN ≥ 400mVpk, tr/tf ≤ 300ps, RL = 50Ω to VCC–2V, TA = 25°C, unless otherwise stated.
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Singled-Ended and Differential Swings
Figure 1b. Differential Voltage Swing
Figure 1a. Single-Ended Voltage Swing
Input and Output Stages
Figure 2b. Simplified LVPECL Output Stage
Figure 2a. Simplified Differential Input Stage
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Input Interface Applications
Option: may connect VT to VCC
Figure 3a. LVPECL Interface
(DC-Coupled)
Figure 3b. LVPECL Interface
(AC-Coupled)
Figure 3d. CML Interface
(AC-Coupled)
Figure 3e. LVDS Interface
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Figure 3c. CML Interface
(DC-Coupled)
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LVPECL Output Interface Applications
LVPECL has a high input impedance, a very low
output impedance (open emitter), and a 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-Thevenin
Equivalent,
Parallel
Termination
(3-resistor),
and
AC-coupled
Termination. Unused output pairs may be left
floating. However, single-ended outputs must be
terminated, or balanced.
Figure 4a. Parallel Termination-Thevenin Equipment
Figure 4b. Parallel Termination (3-Resistor)
Part Number
Function
Data Sheet Link
SY89841U
Precision LVDS Runt Pulse Eliminator 2:1
Multiplexer
www.micrel.com/product-info/products/sy89841u.shtml
SY89842U
Precision CML Runt Pulse Eliminator 2:1
Multiplexer
www.micrel.com/product-info/products/sy89842u.shtml
HBW Solutions
New Products and Applications
www.micrel.com/product-info/products/solutions.shtml
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SY89840U
QFN - 16
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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