MAXIM MAX3736ETE

19-3116; Rev 0; 12/03
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
Features
The MAX3736 is a compact, +3.3V multirate laser driver
for SFP/SFF applications up to 3.2Gbps. The device
accepts differential data and provides bias and modulation currents for driving a laser. DC-coupling to the laser
allows for multirate applications, and reduces the number of external components.
The wide 5mA to 60mA (85mA AC-coupled) modulation
current range and 1mA to 100mA bias current make the
MAX3736 ideal for driving FP/DFB laser diodes in fiberoptic modules. The laser current setting can be controlled by a current DAC, a voltage DAC, or a resistor.
Very low power dissipation, small package size, and
reduced component count, make this part an ideal solution for SFP-module applications.
The MAX3736 is available in dice or in a small 3mm x
3mm, 16-pin thin QFN package. It operates over a -40°C
to +85°C temperature range.
♦ Fully Compatible with SFP and SFF-8472
Specifications
♦ Programmable Modulation Current from 5mA to
60mA (DC-Coupled)
♦ Programmable Modulation Current from 5mA to
85mA (AC-Coupled)
♦ Programmable Bias Current from 1mA to 100mA
♦ 56ps Edge Transition Times
♦ 22mA (typ) Power-Supply Current
♦ Multirate Operation Up to 3.2Gbps
♦ On-Chip Pullup Resistor for DIS
♦ 16-Pin, 3mm × 3mm Thin QFN Package
Applications
Ordering Information
Gigabit Ethernet SFP/SFF Transceiver Modules
PART
1G/2G Fibre-Channel SFP/SFF Transceiver
Modules
Multirate OC-3 to OC-48 FEC SFP/SFF
Transceiver Modules
TEMP RANGE
PIN-PACKAGE
MAX3736E/D
-40°C to +85°C
Dice*
MAX3736ETE
-40°C to +85°C
16 Thin QFN
*Dice are designed to operate from -40°C to +85°C, but are tested and guaranteed only at TA = +25°C.
Pin Configuration appears at end of data sheet.
10G Ethernet LX-4 Modules
Typical Application Circuit
HOST BOARD
SFP OPTICAL TRANSMITTER
+3.3V
SUPPLY FILTER
HOST FILTER
15Ω
56Ω
0.01µF
VCC
VCC_RX
0.1µF
OUT-
8.2pF
IN+
50Ω
10Ω
0.1µF
TX_DISABLE
MOD-DEF1
MOD-DEF2
BIASSET
DIS
MODSET
MAX3736
INBC_MON
50Ω
OUT+
BIAS
GND
SERDES
FERRITE
BEAD
LASER CONTROLLER
________________________________________________________________ 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
MAX3736
General Description
MAX3736
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
ABSOLUTE MAXIMUM RATINGS
Power-Supply Voltage VCC ..................................-0.5V to +6.0V
Voltage at IN+, IN-, DIS…..…………………-0.5V to (VCC + 0.5V)
Voltage at BC_MON, MODSET, BIASSET .............-0.5V to +3.0V
Voltage at OUT+, OUT-.……………………+0.5V to (VCC + 1.5V)
Voltage at BIAS ............……………………+0.5V to (VCC + 0.5V)
Current into BIAS, OUT+, OUT- ......................-20mA to +150mA
Current into IN+, IN-......…………………………-20mA to +20mA
Continuous Power Dissipation (TA = +85°C)
16-Pin Thin QFN (derate 25mW/°C above +85°C) .............2W
Operating Junction Temperature Range ..........-55°C to +150°C
Storage Temperature Range .............................-55°C to +150°C
Die Attach Temperature ..................................................+400°C
Lead Temperature (soldering, 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.
ELECTRICAL CHARACTERISTICS
(VCC = +2.97V to +3.63V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, IBIAS = 20mA, IMOD = 30mA, TA = +25°C, unless
otherwise noted.) (Note 1)
PARAMETER
Power-Supply Current
SYMBOL
CONDITIONS
ICC
Excludes the laser bias and modulation
currents (Note 2)
VID
VID = VIN+ - VIN-, Figure 1
MIN
TYP
MAX
UNITS
22
35
mA
2.4
VP-P
I/O SPECIFICATIONS
Differential Input Voltage
Common-Mode Input Voltage
0.2
0.6 ×
VCC
VINCM
V
Differential Input Resistance
RIN
85
100
115
Ω
DIS Input Pullup Resistance
RPULL
4.7
7.2
10.0
kΩ
VDIS = VCC
DIS Input Current
15
VDIS = GND, VCC = 3.3V, RPULL = 7.4kΩ
DIS Input High Voltage
VIH
DIS Input Low Voltage
VIL
-450
2.0
µA
V
0.8
V
100
mA
100
µA
BIAS GENERATOR
Bias Current Range
Bias Off-Current
BIASSET Current Gain
IBIAS
IBIASOFF
GBIAS
Current into BIAS pin
1
Current into BIAS pin, DIS asserted high
(Note 3)
5mA ≤ IBIAS ≤ 10mA
70
85
95
10mA ≤ IBIAS ≤ 100mA
79
85
91
A/A
BIASSET Current Gain Stability
10mA ≤ IBIAS ≤ 100mA (Note 4)
-4.4
+4
%
BIASSET Current Gain Linearity
10mA ≤ IBIAS ≤ 100mA (Note 5)
-2.3
+2.3
%
Bias Overshoot
During SFP module hot plugging;
see Figure 3 (Notes 5, 6)
10
%
Bias-Current Monitor Gain
(Note 5)
1mA ≤ IBIAS ≤ 5mA
Bias-Current Monitor Gain
Stability (Notes 4, 5)
Modulation Current Range
2
13.7
IMOD
|4|
|2.8|
|2.4|
mA/A
5mA ≤ IBIAS ≤ 10mA
-7
10mA ≤ IBIAS ≤ 100mA
-5
Current into OUT+, RL = 15Ω,
VOUT+ and VOUT- ≥ 0.6V (DC-coupled)
5
60
Current into OUT+, RL = 15Ω,
VOUT+ and VOUT- ≥ 2.0V (AC-coupled)
5
85
+7
%
+5
mAP-P
_______________________________________________________________________________________
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
(VCC = +2.97V to +3.63V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, IBIAS = 20mA, IMOD = 30mA, TA = +25°C, unless
otherwise noted.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
MODULATOR
Modulation Current Gain
GMOD
(Note 3)
5mA ≤ IMOD ≤ 10mA
70
85
95
10mA ≤ IMOD ≤ 85mA
79
85
91
Modulation Current Gain Stability
10mA ≤ IMOD ≤ 85mA (Notes 4, 5)
-4.4
Modulation Current Gain Linearity
10mA ≤ IMOD ≤ 85mA (Note 5)
-3.3
Bias Current Gain and
Modulation Current Gain
Matching (Notes 5, 7)
Modulation OFF Current
+4
%
+3.3
%
IBIASSET = 0.15mA; IMODSET = 0.7mA
2.3
IBIASSET = IMODSET = 0.15mA
0.1
1.4
IBIASSET = IMODSET = 0.4mA
0.1
1
IBIASSET = IMODSET = 0.6mA
0.1
1
IBIASSET = IMODSET = 0.9mA
0.1
1
100
µA
tR
20% to 80%; 10mA ≤ IMOD ≤ 60mA (Note 5)
48
80
ps
Fall Time
tF
80% to 20%; 10mA ≤ IMOD ≤ 60mA (Note 5)
58
80
ps
10mA ≤ IMOD ≤ 60mA; 2.67Gbps;
223-1 PRBS
16
38
10mA ≤ IMOD ≤ 60mA; 3.2Gbps;
K28.5 pattern
17
38
10mA ≤ IMOD ≤ 60mA; 155Mbps;
223-1 PRBS
30
10mA ≤ IMOD ≤ 60mA; 3.2Gbps; K28.5;
TA = +100°C
6.3
10mA ≤ IMOD ≤ 60mA (Note 5)
0.6
Random Jitter
DIS asserted high
%
Rise Time
Deterministic Jitter
(Notes 5, 8)
IMODOFF
A/A
psP-P
ps
1
psRMS
Note 1: Specifications at -40°C are guaranteed by design and characterization. Dice are tested at TA = +25°C only.
Note 2: Maximum value is specified at IMOD = 60mA and IBIAS = 100mA. BC_MON connected to VCC.
Note 3: Modulation current gain, GMOD, is defined as GMOD = IMOD / IMODSET. Bias current gain, GBIAS, is defined as GBIAS =
IBIAS / IBIASSET. The nominal gain is measured at VCC = +3.3V and TA = +25°C.
Note 4: Gain stability is defined as [(Gain) - (Nom_Gain)] / (Nom_Gain) over the listed current range, temperature, and supply
variation. Nominal gain is measured at VCC = +3.3V, TA = +25°C. The voltage at the BC_MON pin must not exceed 1.39V.
Note 5: Guaranteed by design and characterization; see Figure 2.
Note 6: VCC turn-on time must be less than 0.8s, DC-coupled interface.
Note 7: The gain matching is defined as ABS [(GMOD/GBIAS - GMODNOM/GBIASNOM)/(GMODNOM/GBIASNOM)] over the specified
temperature and voltage supply range.
Note 8: For supply noise tolerance, noise is added to the supply (100mVP-P) up to 2MHz; see Figure 3.
_______________________________________________________________________________________
3
MAX3736
ELECTRICAL CHARACTERISTICS (continued)
VOLTAGE
VIN+
VIN-
VCC
VCC
100mV MIN
1200mV MAX
25Ω
26Ω
OUT-
(VIN+) - (VIN-)
30Ω
200mVP-P MIN
2400mVP-P MAX
MAX3736
CURRENT
IOUT+
1.1pF
OSCILLOSCOPE
OUT+
IOUT+
IMOD
Figure 1. Definition of Single-Ended Input Voltage Range
SOURCE
NOISE
VOLTAGE
SUPPLY
50Ω
130Ω
Figure 2. Output Termination for Characterization
HOST BOARD
FILTER DEFINED BY SFP MSA
MODULE
TO LASER
DRIVER VCC
OPTIONAL
1µH
0.1µF
10µF
OPTIONAL
0.1µF
Figure 3. Supply Filter
Typical Operating Characteristics
(Typical values are at VCC = 3.3V, IBIAS = 20mA, IMOD = 30mA, TA = +25°C, unless otherwise noted.)
ER = 8.2dB, OC-48 FILTER
231 - 1 PRBS, 1310 FP LASER
ELECTRICAL EYE
(2.488Gbps)
MAX3736 toc02
117 MHz FILTER, 231 - 1 PRBS
1310nm FP LASER
OPTICAL EYE
(2.488Gbps)
1870MHz FILTER
223 - 1 PRBS
C4
919ps/div
4
58ps/div
58ps/div
_______________________________________________________________________________________
MAX3736 toc03
OPTICAL EYE
(155Mbps)
MAX3736 toc01
MAX3736
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
BIAS CURRENT MONITOR GAIN
vs. TEMPERATURE
70
80
MAX3736 toc06
EXCLUDES IBIAS AND IMOD
18
70
60
50
40
IMOD (mAP-P)
GAIN (mA/A)
60
16
14
30
50
40
30
20
12
20
10
10
10
-40
-15
10
35
60
85
0
-40
TEMPERATURE (°C)
-15
10
35
60
1
85
RMODSET (kΩ)
EDGE TRANSITION TIME
vs. MODULATION AMPLITUDE
80
70
60
50
40
30
20
80
MAX3736 toc09
90
70
EDGE TRANSITION TIME (ps)
MAX3736 toc08
100
100
10
TEMPERATURE (°C)
BIAS CURRENT vs. BIAS RESISTANCE
IBIAS (mA)
SUPPLY CURRENT (mA)
20
MAX3736 toc05
80
MODULATION CURRENT
vs. MODSET RESISTANCE (ZL = 15Ω)
MAX3736 toc07
SUPPLY CURRENT vs. TEMPERATURE
FALL TIME
60
50
40
RISE TIME
30
20
10
0
10
1
10
RBIASSET (kΩ)
100
10
20
30
40
50
60
IMOD (mA)
_______________________________________________________________________________________
5
MAX3736
Typical Operating Characteristics (continued)
(Typical values are at VCC = 3.3V, IBIAS = 20mA, IMOD = 30mA, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(Typical values are at VCC = 3.3V, IBIAS = 20mA, IMOD = 30mA, TA = +25°C, unless otherwise noted.)
DETERMINISTIC JITTER
vs. MODULATION CURRENT
DIFFERENTIAL S11 vs. FREQUENCY
MAX3736 toc11
2.7Gbps
223-1 PRBS
50
0
MAX3736 toc10
60
-5
-10
IS11I (dB)
40
DJ (psP-P)
MAX3736
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
30
-15
20
-20
10
-25
-30
0
10
20
30
40
50
0
60
2
4
6
8
10
FREQUENCY (GHz)
IMOD (mAP-P)
Pin Description
6
PIN
NAME
FUNCTION
1, 4, 9,
12, 15
VCC
2
IN+
Noninverted Data Input
3
IN-
Inverted Data Input
5
BIASSET
A current DAC, a voltage DAC, or a resistor, connected from this pin to ground, sets the desired bias
current for the laser (see the Programming the Laser Bias Current section).
6
MODSET
A current DAC, a voltage DAC, or a resistor, connected from this pin to ground, sets the desired bias
current for the laser (see the Programming the Laser Modulation Current section).
7
BC_MON
Bias Current Monitor Output. Current out of this pin develops a ground-referenced voltage across an
external resistor that is proportional to the bias current.
8
BIAS
10
OUT+
Noninverted Modulation Current Output. IMOD flows into this pin when input data is high.
11
OUT-
Inverted Modulation Current Output. IMOD flows into this pin when input data is low.
13, 14
GND
Ground
16
DIS
EP
Exposed
Pad
+3.3V Supply Voltage. All pins must be connected to VCC.
Laser Bias Current Output
Transmitter Disable, TTL. Laser output is disabled when DIS is asserted high or left
unconnected. The laser output is enabled when this pin is asserted low.
Ground. Must be soldered to the circuit board ground for proper thermal and electrical performance
(see the Exposed Pad Package section).
_______________________________________________________________________________________
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
MAX3736
DIS
VCC
VCC
82pF
16kΩ
7.2kΩ
OUT+
24kΩ
50Ω
OUT-
50Ω
IN+
IN-
VCC
VCC
BIAS
VCC
x1
x85
x85
BC_MON
1.2V
1.2V
MAX3736
BIASSET
MODSET
Figure 4. Functional Diagram
Detailed Description
The MAX3736 laser driver consists of three operational
blocks: a bias current generator, a modulation current
generator, and a high-speed modulation path. The
laser-biasing block includes a monitor output for biassensing purposes. Both the bias and modulation generating blocks are enabled and disabled by the DIS pin.
The high-speed modulation path provides a 100Ω
differential input resistance.
Bias Current Monitor
The MAX3736 features a bias current monitor
(BC_MON). This monitor is realized by mirroring a fraction of the bias current and developing a voltage
across an external resistor connected to ground. For
example, connecting a 100Ω resistor to ground gives
the following relationship:
VBC_MON = (IBIAS / 73) x 100Ω. For compliance, the
voltage on BC_MON must be kept below 1.39V.
Bias Current Generator
Modulation Current Generator
To maintain constant average optical power, the
MAX3736 is designed to interface to a laser controller
IC. The laser controller IC controls the MAX3736, and
maintains a constant laser power using an automatic
power-control (APC) circuit. A back-facet photodiode,
mounted in the laser package, is used to convert the
optical power into a photocurrent. The laser controller
IC adjusts the laser bias current so the monitor photodiode’s current matches the level programmed by the
user. It does this by adjusting the current sourced by
the MAX3736’s BIASSET pin. The MAX3736 reacts by
increasing or decreasing the laser current at BIAS.
The laser’s modulation amplitude can be controlled by
placing a resistor from MODSET to ground. To set the
modulation amplitude, see the I MOD vs. R MODSET
graph in the Typical Operating Characteristics. A more
advanced control scheme employs the use of a laser
controller IC to control modulation current to
stabilize the extinction ratio. For more information on
controlling the extinction ratio refer to Maxim
Application Note HFAN-02.3.1: Maintaining Average
Power and Extinction Ratio, Part 1, Slope Efficiency and
Threshold Current.
_______________________________________________________________________________________
7
MAX3736
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
High-Speed Modulation Driver
The output stage is composed of a high-speed differential pair and a programmable modulation current
source. The MAX3736 is optimized for driving a 15Ω
load; the minimum instantaneous voltage required at
OUT+ is 0.6V. Modulation current swings up to 60mA
are possible.
To interface with the laser diode, a damping resistor
(RD) is required for impedance matching. The combined resistance of the series damping resistor and the
equivalent series resistance of the laser diode should
equal 15Ω. To reduce optical output aberrations and
duty-cycle distortion caused by laser diode parasitic
inductance, an RC shunt network might be necessary.
Refer to Maxim Application Note HFAN 02.0:
Interfacing Maxim’s Laser Drivers to Laser Diodes for
more information.
At high data rates, e.g., 2.5Gbps, any capacitive load at
the cathode of a laser diode degrades optical output performance. Because the BIAS output is directly connected
to the laser cathode, minimize the parasitic capacitance
associated with the pin by using an inductor to isolate the
BIAS pin parasitics from the laser cathode.
In the absence of input data, the modulation current
switches to OUT-, squelching the transceiver output.
Disable
The DIS pin disables the modulation and bias current.
The typical enable time is 2µs for bias current and 1µs
for modulation current. The typical disable time is 200ns
for bias current and 250µs for modulation current. The
DIS pin has a 7.4kΩ internal pullup resistor.
Design Procedure
Programming the Modulation Current
There are three methods for setting the modulation current on the MAX3736 laser driver. The current can be
set by using a current DAC, a voltage DAC in series with
a resistor, or by using a resistor connected to GND.
To program the laser modulation current using a current DAC, attach the DAC to the MODSET pin and set
the current using the following equation:
To program the laser modulation current using a voltage DAC, attach the DAC to the MODSET pin through a
series resistor, RSERIES, and set the current using the
following equation:
IMOD =
1.2V − VDAC
× 85
RSERIES
To program the laser modulation current using a resistor, place the resistor from MODSET to ground. IMOD
current can be calculated by the following equation:
IMOD =
1.2V
× 85
RMODSET
Programming the Bias Current
There are three methods for setting the bias current on
the MAX3736 laser driver. The current can be set by
using a current DAC, a voltage DAC in series with a
resistor, or by using a resistor connected to GND.
To program the laser bias current using a current DAC,
attach the DAC to the BIASSET pin and set the current
using the following equation:
IBIAS = IBIASET × 85
To program the laser bias current using a voltage DAC,
attach the DAC to the BIASSET pin through a series
resistor, RSERIES, and set the current using the following equation:
IBIAS =
1.2V − VDAC
× 85
RSERIES
To program the laser bias current using a resistor,
place the resistor from BIASSET to ground. IBIAS current can be calculated by the following equation:
IBIAS =
1.2V
RBIASET
× 85
IMOD = IMODSET × 85
8
_______________________________________________________________________________________
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
MAX3736
VCC
VCC
MAX3736
82pF
PACKAGE
16kΩ
MAX3736
PACKAGE
VCC
0.43nH
IN+
OUT-
0.65nH
0.11pF
0.11pF
0.43nH
50Ω
OUT+
0.11pF
VCC
50Ω
IN0.11pF
0.65nH
24kΩ
Figure 5. Simplified Input Circuit Schematic
Input Termination Requirements
The MAX3736 data inputs are SFP MSA compliant. Onchip 100Ω, differential input impedance is provided for
optimal termination (Figure 5). Because of the on-chip
biasing network, the MAX3736 inputs self-bias to the
proper operating point to accommodate AC-coupling.
Applications Information
Data Input Logic Levels
The MAX3736 is directly compatible with +3.3V reference
CML. Either DC or AC-coupling can be used for CML referenced to +3.3V. For all other logic types, AC-coupling
should be used. DC coupling to CML is fine, but it
negates the squelching function on the modulation path.
Modulation Currents Exceeding 60mA
For applications requiring a modulation current greater
than 60mA, headroom is insufficient for proper operation
of the laser driver if the laser is DC-coupled. To avoid
this problem, the MAX3736 modulation output can be
AC-coupled to the cathode of a laser diode. An external
pullup inductor is necessary to DC-bias the modulation
output at VCC. Such a configuration isolates laser forward voltage from the output circuitry and allows the output at OUT+ to swing above and below the supply
voltage (VCC). When AC-coupled, the MAX3736 modula-
Figure 6. Simplified Output Circuit Schematic
tion current can be programmed from 5mA to 85mA.
Refer to Maxim Application Note HFAN 02.0: Interfacing
Maxim’s Laser Drivers to Laser Diodes for more information on AC-coupling laser drivers to laser diodes.
Interface Models
Figures 5 and 6 show simplified input and output circuits for the MAX3736 laser driver. If dice are used,
replace package parasitic elements with bondwire parasitic elements.
Wire-Bonding Die
The MAX3736 uses gold metalization with a thickness
of 5µm (typ). Maxim characterized this circuit with goldwire ball bonding (1-mil diameter wire). Die-pad size is
94 mils (2388µm) square, and die thickness is 15 mils
(381µm). Refer to Maxim Application Note HFAN08.0.1: Understanding Bonding Coordinates and
Physical Die Size for additional information.
Layout Considerations
To minimize loss and crosstalk, keep the connections
between the MAX3736 output and the laser as short as
possible. Use good high-frequency layout techniques
and multilayer boards with an uninterrupted ground
plane to minimize EMI and crosstalk.
_______________________________________________________________________________________
9
Exposed-Pad Package
VCC
1
IN+
2
Laser Safety and IEC 825
GND
GND
TOP VIEW
VCC
Pin Configuration
DIS
16
15
14
13
12 VCC
11 OUT-
MA3736
3
10 OUT+
VCC
4
9
5
6
7
8
BIAS
IN-
BC_MON
Using the MAX3736 laser driver alone does not ensure
that a transmitter design is compliant with IEC 825. The
entire transmitter circuit and component selections must
be considered. Customers must determine the level of
fault tolerance required by their application. Please recognize that Maxim products are not designed or authorized for use as components in systems intended for
surgical implant into the body, for applications intended
to support or sustain life, or for any other application
where the failure of a Maxim product could create a situation where personal injury or death may occur.
MODSET
The exposed pad on the 16-pin QFN provides a very
low thermal resistance path for heat removal from the
IC. The pad is also electrical ground on the MAX3736
and must be soldered to the circuit board ground for
proper thermal and electrical performance. Refer to
Maxim Application Note HFAN-08.1: Thermal
Considerations for QFN and Other Exposed-Pad
Packages for additional information.
BIASSET
MAX3736
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
VCC
THIN QFN (3mm x 3mm)
THE EXPOSED PAD MUST BE CONNECTED TO GROUND
FOR PROPER THERMAL AND ELECTRICAL PERFORMANCE
Chip Topography/
Pad Configuration
The origin for pad coordinates is defined as the bottom
left corner of the bottom left pad. All pad locations are
referenced from the origin, and indicate the center of
the pad where the bond wire should be connected.
Refer to Maxim Application Note HFAN-08.0.1:
Understanding Bonding Coordinates and Physical Die
Size for detailed information.
TRANSISTOR COUNT: 1385
PROCESS: SiGe BIPOLAR
SUBSTRATE CONNECTED TO GND
DIE THICKNESS: 15 mils
Chip Topography
GND
DIS VCC GND GND GND
VCC
VCC
OUT-
IN+
OUT-
IN-
1.14mm
OUT+ (45mils)
OUT+
VCC
VCC
(0,0)
BIASSET MODSET BC_MON
BIAS
1.55mm
(61mils)
10
______________________________________________________________________________________
3.2Gbps, Low-Power, Compact,
SFP Laser Driver
Table 1. MAX3736 Bondpad Locations
Package Information
For the latest package outline information, go to
www.maxim-ic.com/packages.
COORDINATES (µm)
PAD
NUMBER
PAD NAME
BP1
VCC
BP2
IN+
0
351.4
BP3
IN-
0
169.4
X
Y
0
520.8
BP4
VCC
0
0
BP5
BIASSET
298.3
-222.1
BP6
MODSET
526.5
-222.1
BP7
BC_MON
737.7
-223.5
BP8
BIAS
1104.8
-224.9
BP9
VCC
1258.9
-107.9
BP10
OUT+
1258.9
32.1
BP11
OUT+
1258.9
179.1
BP12
OUT-
1258.9
342.9
BP13
OUT-
1258.9
490
BP14
VCC
1258.9
629.9
BP15
GND
1060
630.9
BP16
GND
896.1
632.3
BP17
GND
712.7
630.9
BP18
VCC
550.3
630.9
BP19
DIS
378.1
631
BP20
GND
191.8
630.9
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
© 2003 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX3736
Bonding Coordinates