MAXIM MAX9426EHJ

19-2390; Rev 0; 4/02
Lowest Jitter Quad PECL-to-ECL
Differential Translators
The MAX9424–MAX9427 high-speed, low-skew quad
PECL-to-ECL translators are designed for high-speed
data and clock driver applications. These devices feature
an ultra-low 0.24ps(RMS) random jitter and channel-tochannel skew is less than 90ps in asynchronous mode.
The four channels can be operated synchronously with
an external clock, or in asynchronous mode determined
by the state of the SEL input. An enable input provides
the ability to force all the outputs to a differential low state.
The parts differ from one another by their input and output termination options. The input options are an open
input or an internal differential 100Ω termination. The
output options are an open-emitter output or a series
50Ω termination. See Ordering Information.
The MAX9424–MAX9427 operate from a positive voltage
supply of +2.375V to +5.5V, and a negative supply voltage of -2.375V to -5.5V and operate across the extended
temperature range of -40°C to +85°C. They are offered in
32-pin 5mm x 5mm TQFP and space-saving 5mm x 5mm
QFN packages.
Applications
Data and Clock Driver and Buffer
Central Office Backplane Clock Distribution
DSLAM Backplane
Base Station
ATE
Features
♦ 0.24ps RMS Added Random Jitter
♦ 10ps Channel-to-Channel Skew in Synchronous
Mode
♦ Guaranteed 500mV Differential Output at 3GHz
Clock Frequency
♦ 420ps Propagation Delay in Asynchronous Mode
♦ Functionally Compatible with
SK4426 (MAX9424)
SK4430 (MAX9425)
SK4436 (MAX9426)
SK4440 (MAX9427)
♦ Integrated 50Ω Outputs (MAX9425/MAX9427)
♦ Integrated 100Ω Inputs (MAX9426/MAX9427)
♦ Synchronous/Asynchronous Operation
Ordering Information
INPUT OUTPUT
(IN_, (OUT_,
OUT_)
IN_)
MAX9424EHJ -40°C to +85°C 32 TQFP
Open
Open
MAX9424EGJ* -40°C to +85°C 32 QFN
Open
Open
MAX9425EHJ -40°C to +85°C 32 TQFP
Open
50Ω
MAX9425EGJ* -40°C to +85°C 32 QFN
Open
50Ω
MAX9426EHJ -40°C to +85°C 32 TQFP
100Ω
Open
MAX9426EGJ* -40°C to +85°C 32 QFN
100Ω
Open
MAX9427EHJ -40°C to +85°C 32 TQFP
100Ω
50Ω
MAX9427EGJ* -40°C to +85°C 32 QFN
100Ω
50Ω
*Future product—contact factory for availability.
TEMP
RANGE
PART
PINPACKAGE
Pin Configurations
OUT0
OUT0
VEE
IN1
IN1
27
26
25
25
28
26
VGG
IN1
27
29
IN1
28
IN0
VEE
29
30
OUT0
30
IN0
OUT0
31
31
VGG
32
32
IN0
TOP VIEW
IN0
TOP VIEW
*
*
VCC
1
24 VGG
VCC
24
VGG
SEL
2
23 OUT1
SEL
2
23
OUT1
SEL
3
22 OUT1
SEL
3
22
OUT1
CLK
4
21 VEE
CLK
4
21
VEE
CLK
5
20
VEE
EN
6
19
OUT2
EN
7
18
OUT2
VCC
8
17
VGG
VEE
IN2
IN2
16
OUT3
IN2
OUT3
TQFP (5mm x 5mm)
15
16
IN2
15
14
14
VEE
13
13
12
OUT3
11
VGG
IN3
10
IN3
*
9
12
17 VGG
8
OUT3
18 OUT2
11
VCC
19 OUT2
VGG
7
9
6
EN
10
EN
20 VEE
IN3
5
MAX9424
MAX9425
MAX9426
MAX9427
IN3
CLK
MAX9424
MAX9425
MAX9426
MAX9427
1
*
QFN
NOTE: CORNER PINS ARE CONNECTED TO VGG.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX9424–MAX9427
General Description
MAX9424–MAX9427
Lowest Jitter Quad PECL-to-ECL
Differential Translators
ABSOLUTE MAXIMUM RATINGS
VCC to VGG ............................................................-0.3V to +6.0V
VGG to VEE.............................................................-0.3V to +6.0V
Input Pins to VGG ........................................-0.3V to (VCC + 0.3V)
Differential Input Voltage ..............................|VCC - VGG| or 3.0V,
whichever is less
Continuous Output Current .................................................50mA
Surge Output Current........................................................100mA
Continuous Power Dissipation (TA = +70°C)
32-Pin 5mm x 5mm TQFP
(derate 9.5mW/°C above +70°C) .................................761mW
32-Pin 5mm x 5mm QFN
(derate 21.3mW/°C above +70°C) ...................................1.7W
Junction-to-Ambient Thermal Resistance in Still Air
32-Pin 5mm x 5mm TQFP ........................................+105°C/W
32-Pin 5mm x 5mm QFN............................................+47°C/W
Junction-to-Ambient Thermal Resistance with
500LFPM Airflow
32-Pin 5mm x 5mm TQFP ..........................................+73°C/W
Junction-to-Case Thermal Resistance
32-Pin 5mm x 5mm TQFP ..........................................+25°C/W
32-Pin 5mm x 5mm QFN..............................................+2°C/W
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
ESD Protection
Human Body Model (all input pins) ...............................±500V
Human Body Model (all output pins) ...............................±2kV
Soldering Temperature (10s) ...........................................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
DC ELECTRICAL CHARACTERISTICS
(VCC - VGG = 2.375V to 5.5V, VGG - VEE = 2.375V to 5.5V, MAX9424/MAX9426 outputs terminated with 50Ω to VGG - 2.0V,
MAX9425/MAX9427 not externally terminated, TA = -40°C to +85°C. Typical values are at VCC - VGG = 3.3V, VGG - VEE = 3.3V, VIHD
= VCC - 0.9V, VILD = VCC - 1.7V, TA = +25°C, unless otherwise noted.) (Notes 1, 2, and 3)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
VCC
V
INPUTS (IN_, IN_, CLK, CLK, EN, EN, SEL, SEL)
Differential Input High Voltage
VIHD
Figure 1
VGG +
1.4
Differential Input Low Voltage
VILD
Figure 1
VGG
Differential Input Voltage
VID
Figure 1
Input Current
Differential Input Resistance
(IN_, IN_)
IIH, IIL
RIN
MAX9424/
MAX9425
MAX9426/
MAX9427
VCC 0.2
VCC VGG
VCC - VGG < 3.0V
0.2
VCC - VGG ≥ 3.0V
0.2
3.0
-10
25
-10
25
EN, EN, SEL, SEL, IN_, IN_, CLK
or CLK = VIHD or VILD
EN, EN, SEL, SEL, CLK, or CLK
= VIHD or VILD
MAX9426/MAX9427
V
V
µA
86
100
114
Ω
OUTPUTS (OUT_, OUT_)
Differential Output Voltage
VOH - VOL
Figure 1
600
635
VGG 1.25
50
VGG 1.05
60
Ω
8
10
mA
mA
Output Common-Mode Voltage
VOCM
Figure 1
Output Impedance
ROUT
MAX9425/MAX9427
VGG 1.50
40
Internal Current Source
ISINK
MAX9425/MAX9427
6
mV
V
POWER SUPPLY
Positive Supply Current
Negative Supply Current
2
ICC
IEE
(Note 4)
16
27
MAX9424/MAX9426 (Note 4)
100
130
MAX9425/MAX9427 (Note 4)
172
230
_______________________________________________________________________________________
mA
Lowest Jitter Quad PECL-to-ECL
Differential Translators
(VCC - VGG = 2.375V to 5.5V, VGG - VEE = 2.375V to 5.5V, outputs terminated with 50Ω to VGG - 2.0V, EN = VIHD, EN = VILD, fCLK ≤
3.0GHz, fIN ≤ 1.5GHz, input transition time = 125ps (20% to 80%), VIHD = VGG + 1.4V to VCC, VILD = VGG to VCC - 0.2V, VIHD - VILD
= 0.2V to smallest of |VCC - VGG| or 3.0V, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VCC - VGG = 3.3V, VGG
- VEE = 3.3V, VIHD = VCC - 0.9V, VILD = VCC - 1.7V, TA = +25°C, unless otherwise noted.) (Notes 1 and 5)
PARAMETER
SYMBOL
IN_ to OUT_ Differential
Propagation Delay
CLK to OUT_ Differential
Propagation Delay
tPLH1
tPHL1
tPLH2
tPHL2
OUT_ to OUT_ Skew
tSKD1
OUT_ to OUT_ Skew
tSKD2
Maximum Clock Frequency
fCLK(MAX)
Maximum Data Frequency
fIN(MAX)
Added Random Jitter
tRJ
MIN
TYP
MAX
UNITS
Figure 3, SEL = high, asynchronous
operation
CONDITIONS
300
420
570
ps
Figure 4, SEL = low, synchronous operation
460
580
730
ps
38
90
ps
10
70
ps
SEL = high, asynchronous operation
(Note 6)
SEL = low, synchronous operation (Note 6)
MAX9424/MAX9426, VOH - VOL ≥ 500mV,
SEL = low
MAX9425/MAX9427, VOH - VOL ≥ 300mV,
SEL = low
MAX9424/MAX9426, VOH - VOL ≥ 400mV,
SEL = high
MAX9425/MAX9427, VOH - VOL ≥ 250mV,
SEL = high
SEL = low, fCLK = 3.0GHz clock, fIN =
1.5GHz (Note 7)
3.0
GHz
2.0
GHz
SEL = high, fIN = 2.0GHz (Note 7)
Added Deterministic Jitter
tDJ
SEL = low, fCLK = 3.0GHz, IN_ = 3.0Gbps
223 - 1 PRBS pattern (Note 7)
SEL = high, IN_ = 2.0Gbps 223 - 1 PRBS
pattern (Note 7)
0.24
0.8
0.3
0.8
27
80
20
80
ps(RMS)
ps(P-P)
IN_ to CLK Setup Time
tS
Figure 4
80
ps
CLK to IN_ Hold Time
tH
Figure 4
80
ps
Output Rise Time
tR
Figure 3
89
120
ps
Output Fall Time
tF
Figure 3
87
120
ps
0.2
1
ps/°C
Propagation Delay Temperature
Coefficient
∆tPD/∆T
Note 1: Measurements are made with the device in thermal equilibrium.
Note 2: Current into a pin is defined as positive. Current out of a pin is defined as negative.
Note 3: DC parameters are production tested at +25°C. DC limits are guaranteed by design and characterization over the full
operating temperature range.
Note 4: All outputs open, all inputs biased differential high or low except VCC, VGG, and VEE.
Note 5: Guaranteed by design and characterization, and are not production tested. Limits are set to ±6 sigma.
Note 6: Measured between outputs of the same part at the signal crossing points for a same-edge transition.
Note 7: Device jitter added to the input signal.
_______________________________________________________________________________________
3
MAX9424–MAX9427
AC ELECTRICAL CHARACTERISTICS
Typical Operating Characteristics
(MAX9424: VCC - VGG = 3.3V, VGG - VEE = 3.3V, outputs terminated with 50Ω to VGG - 2.0V, enabled, fCLK = 3.0GHz, fIN = 1.5GHz,
input transition time = 125ps (20% to 80%), VIHD = VCC - 0.9V, VILD = VCC - 1.7V, TA = +25°C, unless otherwise noted.)
OUTPUT AMPLITUDE (VOH - VOL)
vs. IN_ FREQUENCY
50
ICC
SEL = HIGH
550
500
450
400
350
0
-40
-15
10
35
0.5
1.0
1.5
2.0
IN-TO-OUT PROPAGATION DELAY
vs. TEMPERATURE
RISE TIME
88
86
3.0
2.5
-40
-15
400
tPLH1
390
380
MAX9424–MAX9427 toc05
410
630
CLK-TO-OUT PROPAGATION DELAY (ps)
tPHL1
10
620
610
tPLH2,
tPHL2
600
590
580
570
-40
-15
10
35
TEMPERATURE (°C)
60
85
-40
35
TEMPERATURE (°C)
CLK-TO-OUT PROPAGATION DELAY
vs. TEMPERATURE
MAX9424–MAX9427 toc04
420
IN-TO-OUT PROPAGATION DELAY (ps)
FALL TIME
90
IN_ FREQUENCY (GHz)
TEMPERATURE (°C)
4
92
84
0
85
60
MAX9424–MAX9427 toc03
INPUTS BIASED
DIFFERENTIALLY HIGH OR
LOW, OUTPUTS OPEN
94
MAX9424–MAX9427 toc02
600
OUTPUT AMPLITUDE (mV)
IEE
75
25
650
MAX9424–MAX9427 toc01
100
OUTPUT RISE/FALL TIME
vs. TEMPERATURE
OUTPUT RISE/FALL TIME (ps)
SUPPLY CURRENT vs. TEMPERATURE
SUPPLY CURRENT (mA)
MAX9424–MAX9427
Lowest Jitter Quad PECL-to-ECL
Differential Translators
-15
10
35
60
85
TEMPERATURE (°C)
_______________________________________________________________________________________
60
85
Lowest Jitter Quad PECL-to-ECL
Differential Translators
PIN
NAME
FUNCTION
Positive Supply Voltage. Bypass VCC to VGG with 0.1µF and 0.01µF ceramic capacitors. Place the
capacitors as close to the device as possible with the smaller value capacitor closest to the device.
Noninverting Differential Select Input. Setting SEL = 1 and SEL = 0 enables all four channels to
operate independently. Setting SEL = 0 and SEL = 1 enables all four channels to be synchronized to
CLK.
Inverting Differential Select Input
1, 8
VCC
2
SEL
3
SEL
4
CLK
Noninverting Differential Clock Input
5
CLK
6
EN
7
EN
Inverting Differential Clock Input
Noninverting Differential Output Enable Input. Setting EN = 1 and EN = 0 enables all four outputs.
Setting EN = 0 and EN = 1 disables all four outputs.
Inverting Differential Output Enable Input
9
IN3
Noninverting Differential Input 3
10
11, 17, 24,
30
12
IN3
Inverting Differential Input 3
VGG
Ground Reference
OUT3
Inverting Differential Output 3
13
OUT3
14, 20, 21,
27
VEE
15
IN2
Noninverting Differential Output 3
Negative Supply Voltage. Bypass from VEE to VGG with 0.1µF and 0.01µF ceramic capacitors. Place
the capacitors as close to the device as possible with the smaller value capacitor closest to the
device.
Noninverting Differential Input 2
16
IN2
Inverting Differential Input 2
18
OUT2
Inverting Differential Output 2
19
OUT2
Noninverting Differential Output 2
22
OUT1
Noninverting Differential Output 1
23
OUT1
Inverting Differential Output 1
25
IN1
Inverting Differential Input 1
26
IN1
Noninverting Differential Input 1
28
OUT0
Noninverting Differential Output 0
29
OUT0
Inverting Differential Output 0
31
IN0
Inverting Differential Input 0
32
IN0
Noninverting Differential Input 0
_______________________________________________________________________________________
5
MAX9424–MAX9427
Pin Description
Lowest Jitter Quad PECL-to-ECL
Differential Translators
MAX9424–MAX9427
Functional Diagram
VCC
VGG
11, 17,
24, 30
1, 8
VEE
14, 20,
21, 27
VCC
32
IN0
IN0
1
31
VGG
VCC
28
D
Q
D
Q
29
0
CK
VCC
OUT0
OUT0
VEE
CK
26
IN1
IN1
1
25
VGG
VCC
22
D
Q
D
Q
23
0
CK
OUT1
OUT1
VEE
CK
VCC
15
IN2
IN2
1
16
VGG
VCC
19
D
Q
D
Q
18
0
CK
VCC
OUT2
OUT2
VEE
CK
9
IN3
IN3
1
10
VGG
VCC
13
D
Q
D
Q
12
0
CK
VCC
VEE
CK
4
CLK
CLK
5
2
SEL
SEL
MAX9424
MAX9425
MAX9426
MAX9427
3
6
EN
EN
7
VGG
6
_______________________________________________________________________________________
OUT3
OUT3
Lowest Jitter Quad PECL-to-ECL
Differential Translators
VIHD (MAX)
VID
VGG
VID = 0
VOH
VILD (MAX)
VOH - VOL
VOCM
VIHD (MIN)
VID
MAX9424–MAX9427
VCC
VOL
VID = 0
VGG
VEE
VILD (MIN)
INPUT VOLTAGE DEFINITION
(PECL)
OUTPUT VOLTAGE DEFINITION
(ECL)
Figure 1. Input and Output Voltage Definitions
IN_
IN_
100kΩ
IN_
IN_
MAX9424/MAX9425
MAX9426/MAX9427
VGG
VGG
50Ω
OUT_
50Ω
OUT_
OUT_
OUT_
8mA
8mA
VEE
MAX9424/MAX9426
MAX9425/MAX9427
Figure 2. Input and Output Configurations
Detailed Description
The MAX9424–MAX9427 high-speed, low-skew PECL-toECL differential translators are designed for high-speed
data and clock driver applications. These devices translate up to four PECL signals to ECL signals.
The four channels can be operated synchronously with
an external clock, or in asynchronous mode, determined
by the state of the SEL input. An enable input provides
the ability to force all the outputs to a differential low state.
A variety of input and output terminations are offered
for maximum design flexibility. The MAX9424 has open
inputs and open-emitter outputs. The MAX9425 has
open inputs and 50Ω series outputs. The MAX9426 has
100Ω differential input impedance and open-emitter
outputs. The MAX9427 has 100Ω differential input
impedance and 50Ω series outputs.
Supply Voltages
These devices require a positive voltage supply (connect to VCC), a negative voltage supply (connect to
VEE), and a ground reference (connect to VGG). VCC is
independent of VEE and therefore the supply voltages
do not need to be symmetrical. The PECL input voltages are referenced to VCC, and the ECL output voltages are referenced to VGG.
Data Inputs and Outputs
The input and output structures are shown in Figure 2.
The open inputs of the MAX9424/MAX9425 require
external termination, whereas the MAX9426/MAX9427
have integrated 100Ω differential input termination
resistors between IN_ and IN_.
_______________________________________________________________________________________
7
MAX9424–MAX9427
Lowest Jitter Quad PECL-to-ECL
Differential Translators
IN_
VIHD - VILD
IN_
tPLH1
tPHL1
OUT_
VOH - VOL
OUT_
VOH - VOL
80%
OUT_ - OUT_
VOH - VOL
20%
DIFFERENTIAL OUTPUT
WAVEFORM
80%
20%
tR
tF
SEL = HIGH
EN = HIGH
Figure 3. IN to OUT Propagation Delay and Transition Timing Diagram
CLK
VIHD - VILD
CLK
tH
tS
tH
IN_
VIHD - VILD
IN_
tPLH2
tPHL2
OUT_
VIHD - VILD
OUT_
SEL = LOW
EN = HIGH
Figure 4. CLK to OUT Propagation Delay Timing Diagram
The MAX9425/MAX9427 have internal 50Ω series-output termination resistors and 8mA internal pulldown
current sources, removing the need for external termination. The MAX9424/MAX9426 have open-emitter outputs, which require external termination (see the Output
Termination section).
Enable
Setting EN = high and EN = low enables the device.
Alternatively, setting EN = low and EN = high forces the
outputs to a differential low; all changes on CLK, SEL,
and IN_ are ignored.
8
Asynchronous Operation
Setting SEL = high and SEL = low enables the four channels to operate independently. The clock signal is
ignored in this mode. When asynchronous mode is
selected, drive or bias the CLK and CLK inputs. Biasing
the clock inputs properly is shown in Figure 5. This prevents the unused clock inputs from toggling, which eliminates unnecessary switching noise.
_______________________________________________________________________________________
Lowest Jitter Quad PECL-to-ECL
Differential Translators
IN_
IN_
OUT_
OUT_
100Ω
100Ω
OUT_
IN_
OUT_
IN_
1kΩ
1/4 MAX9424/MAX9425
VGG
1kΩ
1/4 MAX9426/MAX9427
VGG
Figure 5. Input Bias Circuits for Unused Inputs
Synchronous Operation
Power-Supply Bypassing
Setting SEL = low and SEL = high enables all four
channels to operate in synchronous mode where the
buffered inputs are clocked out simultaneously on the
rising edge of the differential clock input (CLK and
CLK). To have the input signals clocked out on the
falling edge, swap the clock lines.
Typically, VGG is directly connected to ground. Bypass
each VCC pin to VGG with high-frequency surface-mount
ceramic 0.01µF capacitors. Place these capacitors as
close to the device as possible. Use the same bypass
capacitor configuration between each VEE pin and VGG.
In high-frequency, high-noise environments, add a 0.1µF
capacitor in parallel with each 0.01µF capacitor.
Use multiple vias when connecting the bypass capacitors to VGG (ground). This reduces trace inductance,
lowering power-supply bounce when drawing high
transient currents.
Differential Signal Input
The maximum input signal magnitude for each of the
devices is VCC - VGG or 3.0V, whichever is less. This
includes IN_, IN_, CLK, CLK, SEL, SEL, EN and EN.
Applications Information
Input Bias
Bias any unused inputs as shown in Figure 5. This
avoids noise coupling that can cause toggling of the
unused outputs.
Output Termination
Terminate the open-emitter outputs (MAX9424/
MAX9426) through 50Ω to VGG - 2V or use equivalent
Thevenin terminations. Terminate both outputs of a differential pair and use identical termination on each for
the lowest output-to-output skew. When a single-ended
signal is taken from a differential output, terminate both
outputs. For example, if OUT0 is used as a singleended output, terminate both OUT0 and OUT0.
Ensure that output currents do not exceed the current
limits as specified in the Absolute Maximum Ratings.
Under all operating conditions, the device’s total thermal limits should be observed.
Circuit Board Traces
Circuit board trace layout is very important to maintain
the signal integrity of high-speed differential signals.
Maintaining integrity is accomplished in part by reducing signal reflections and skew, and increasing common-mode noise immunity.
Signal reflections are caused by discontinuities in the
50Ω characteristic impedance of the traces. Avoid discontinuities by maintaining the distance between differential traces, not using sharp corners, and using vias.
Maintaining distance between the traces also increases
common-mode noise immunity. Reducing signal skew
is accomplished by matching the electrical length of
the differential traces.
Chip Information
TRANSISTOR COUNT: 882
PROCESS: Bipolar
_______________________________________________________________________________________
9
MAX9424–MAX9427
VCC
VCC
MAX9424–MAX9427
Lowest Jitter Quad PECL-to-ECL
Differential Translators
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)
10
______________________________________________________________________________________
Lowest Jitter Quad PECL-to-ECL
Differential Translators
32L TQFP, 5x5x01.0.EPS
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 11
© 2002 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX9424–MAX9427
Package Information (continued)
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)