ONET1151L
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SLLSEI7 – DECEMBER 2013
11.3 Gbps Low-Power Laser Diode Driver
Check for Samples: ONET1151L
FEATURES
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Digitally Selectable Modulation Current up to
85 mApp (10-Ω Load)
Digitally Selectable Bias Current up to 100-mA
Source or Sink
2-Wire Digital Interface With Integrated Digitalto-Analog Converters (DACs) and Analog-toDigital Converter (ADC) for Control and
Diagnostic Management
Automatic Power Control (APC) Loop
Adjustable Output Resistance and DeEmphasis
Programmable Input Equalizer
Cross-Point Control
Selectable Monitor PD Current Range and
Polarity
Includes Laser Safety Features
Single +3.3-V Supply
Temperature –40°C to 100°C
Surface Mount 4-mm × 4-mm, 24-Pin RoHSCompliant QFN Package
Pin-Compatible to the ONET1101L Device
APPLICATIONS
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DESCRIPTION
The ONET1151L device is a 3.3-V laser driver
designed to directly modulate a laser at data rates
from 1 to 11.3 Gbps.
The device provides a 2-wire serial interface, which
allows digital control of the modulation and bias
currents, eliminating the need for external
components. Output waveform control, in the form of
cross-point adjustment, de-emphasis, and output
termination resistance are available to improve the
optical eye mask margin. An optional input equalizer
can be used for equalization of up to 150 mm (6 in.)
of microstrip or stripline transmission line on FR4printed circuit boards. The device contains internal
ADC and DACs to eliminate the need for special
purpose microcontrollers.
The ONET1151L device includes an integrated
automatic power control (APC) loop, which
compensates for variations in laser average power
over voltage and temperature and circuitry to support
laser safety and transceiver management systems.
The laser driver is characterized for operation from
–40°C ambient to +100°C temperatures and is
available in a small footprint 4-mm × 4-mm, 24-pin,
RoHS-compliant QFN package that is pin-compatible
to the ONET1101L device.
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SONET OC-192 and SDH STM-64 Optical
Transmitters
6-G and 10-G CPRI and OBSAI
SFP+ and XFP Transceiver Modules
1
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2013, Texas Instruments Incorporated
ONET1151L
SLLSEI7 – DECEMBER 2013
www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
VCC
MOD+
MOD+
MOD±
MOD±
VCC
24-Pin, RoHS-Compliant, QFN Package, 4 mm x 4 mm
With a Lead Pitch of 0,5 mm
(TOP VIEW)
24 23 22 21 20 19
18 BIAS
PD 1
ADR0 2
17 GND
ONET1101L
ONET1151L
ADR1 3
16 VCC
24 Lead QFN
24-Lead QFN
³ RGE´
DIS 4
15 COMP
SCK 5
14 MONP
SDA 6
13 MONB
RZTC
GND
DIN±
9 10 11 12
DIN+
GND
FLT
7 8
Table 1. PIN DESCRIPTION
PIN
Description
NAME
NO.
ADR0
2
Digital-in
I2C address programming pin. Leave this pad open for a default address of 0001000.
Pulling the pin to VCC changes the first address bit to 1 (address = 0001001).
ADR1
3
Digital-in
I2C address programming pin. Leave this pad open for a default address of 0001000.
Pulling the pin to VCC changes the second address bit to 1 (address = 0001010).
BIAS
18
Analog
Sinks or sources the bias current for the laser in both APC and open loop modes
COMP
15
Analog
Compensation pin used to control the bandwidth of the APC loop. Connect a 0.01-µF
capacitor to ground.
DIN+
9
Analog-in
Noninverted data input. On-chip differentially 100 Ω terminated to DIN–. Must be AC
coupled.
DIN–
10
Analog-in
Inverted data input. On-chip differentially 100 Ω terminated to DIN+. Must be AC coupled.
DIS
4
Digital-in
Disables both bias and modulation currents when set to high state. Includes a 10-kΩ pullup
resistor to VCC. Toggle to reset a fault condition.
FLT
7
Digital-out
Fault detection flag. High level indicates that a fault has occurred. Open-drain output.
Requires an external 4.7-kΩ to 10-kΩ pullup resistor to VCC for proper operation.
GND
2
Type
8, 11, 17, EP Supply
Circuit ground. Exposed die pad (EP) must be grounded.
MOD+
20, 21
CML-out
Noninverted modulation current output. IMOD flows into this pin when input data is high.
MOD–
22, 23
CML-out
Inverted modulation current output. IMOD flows into this pin when input data is low.
MONB
13
Analog-out
Bias current monitor. Sources a 1% replica of the bias current. Connect an external resistor
to ground (GND) to use the analog monitor (DMONB = 0). If the voltage at this pin exceeds
1.16 V, a fault is triggered. Typically choose a resistor to give MONB voltage of 0.8 V at the
maximum desired bias current. If the digital monitor function is used (DMONB = 1), the
resistor must be removed.
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Table 1. PIN DESCRIPTION (continued)
MONP
14
Analog-out
Photodiode current monitor. Sources a 12.5% replica of the photodiode current when
PDRNG = 1X, a 25% replica when PDRNG = 01, and a 50% replica when PDRNG = 00.
Connect an external resistor (5-kΩ typical) to ground (GND) to use the analog monitor
(DMONP = 0). If the voltage at this pin exceeds 1.16 V, a fault is triggered when MONPFLT
= 1. If the digital monitor function is used (DMONP = 1), the resistor must be removed.
PD
1
Analog
Photodiode input. Pin can source or sink current dependent on register setting.
RZTC
12
Analog
Connect external zero TC 28.7-kΩ resistor to ground (GND). Used to generate a defined
zero TC reference current for internal DACs.
SCK
5
Digital-in
2-wire interface serial clock input. Includes a 10-kΩ or 40-kΩ pullup resistor to VCC.
SDA
6
Digital-in
2-wire interface serial data input. Includes a 10-kΩ or 40-kΩ pullup resistor to VCC.
VCC
16, 19, 24
Supply
3.3-V, –15% to +10% supply voltage
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BLOCK DIAGRAM
Figure 1 shows a simplified block diagram of the ONET1151L device. The laser driver consists of:
• Equalizer
• Limiter
• Output driver
• DC offset cancellation with cross-point control
• Power-on reset circuitry
• 2-wire serial interface including:
– Control logic block
– Modulation current generator
• Bias current generator
• Automatic power control loop
• Analog reference block
VCC
Crosspoint
Adjust
To all Blocks Except Output Driver
VCC
DC Offset Cancellation
25
25
OUT+
Equalizer
100
OUT-
Amplifier
Limiter
+
DIN+
+
DIN-
Mod.
Current
Generator
VCC
10 k
10 k
Adjustable
Boost
10 k
8-Bit Register
8-Bit Register
SDA
SDA
SCK
SCK
DIS
DIS
10-Bit Register
10-Bit Register
8-Bit Register
8-Bit Register
8-Bit Register
8-Bit Register
3-Bit Register
Settings
Settings
IMOD
IBIAS
Equalizer
Crosspoint
Output Settings
Limiter Current
Monitor Settings
8-Bit Register
8-Bit Register
Bias Current Fault
PD Current Fault
8-Bit Register
ADC Settings
ADC
ADR0
ADR0
ADR1
ADR1
2-Wire Interface and Control Logic
10-Bit Register
BIAS
Bias
Current MONB
Generator MONP
or Monitor
FLT
and APC
Crosspoint Adjust
MONB
MONP
Analog to
Digital
Conversion
PD
COMP
BIAS
MONB
MONP
FLT
PD
COMP
Band-Gap, Analog References,
Power Supply Monitor, and
Temperature Sensor
Power-On
Reset
PSM
RZTC
TS
RZTC
Figure 1. Simplified Block Diagram of the ONET1151L
4
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ABSOLUTE MAXIMUM RATINGS (1)
Over operating free-air temperature range (unless otherwise noted)
VCC
Supply voltage
(2)
VADR0, VADR1, VDIS, VRZTC,
Voltage at ADR0, ADR1, DIS, RZTC, SCK, SDA, DIN+, DIN–,
VSCK, VSDA, VDIN+, VDIN–, VFLT, FLT, MONB, MONP, COMP, PD, BIAS, MOD+, MOD– (2)
VMONB, VMONP, VCOMP, VPD,
VBIAS, VMOD+, VMOD–
MIN
MAX
–0.3
4.0
–0.3
4.0
IDIN–, IDIN+
Max current at input pins
IMOD+, IMOD–
Max current at output pins
ESD
ESD rating at all pins
TJ
Maximum junction temperature
TSTG
Storage temperature range
–65
150
TC
Case temperature
–40
110
(1)
(2)
UNIT
V
25
mA
120
2
kV (HBM)
125
°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 under “recommended operating
conditions” is not implied. Exposure to absolute–maximum–rated conditions for extended periods may affect device reliability.
All voltage values are with respect to network ground terminal.
RECOMMENDED OPERATING CONDITIONS
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITION
MIN
NOM
MAX
2.8
3.3
3.63
VCC
Supply voltage
VIH
Digital input high voltage
DIS, SCK, SDA, ADR0, ADR1
VIL
Digital input low voltage
DIS, SCK, SDA
Photodiode current range
Control bit PDRNG = 1X, step size = 3 µA
3 080
Control bit PDRNG = 01, step size = 1.5 µA
1 540
UNIT
2
V
0.8
Control bit PDRNG = 00, step size = 0.75 µA
µA
770
RRZTC
Zero TC resistor value (1)
vIN
Differential input voltage swing
150
1200
mVp-p
TC
Temperature at the thermal pad
–40
100
°C
(1)
1.16-V band-gap bias across resistor, E96, 1%
accuracy
28.4
28.7
29
kΩ
Changing the value will alter the DAC ranges.
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DC ELECTRICAL CHARACTERISTICS
Over recommended operating conditions, with a 25-Ω single-ended output load, open-loop operation, IMOD = 30 mA,
IBIAS = 30 mA, and RRZTC = 28.7 kΩ, unless otherwise noted
PARAMETER
VCC
TEST CONDITION
MIN
NOM
MAX
UNIT
2.8
3.3
3.63
V
IMOD = 30 mA, IBIAS = 30 mA, including IMOD and IBIAS,
EQENA = 0
120
135
IMOD = 30 mA, IBIAS = 30 mA, including IMOD and IBIAS,
EQENA = 1
123
140
mA
Supply voltage
IVCC
Supply current
RIN
Data input resistance
Differential between DIN+ and DIN–
80
100
120
Ω
ROUT
Output resistance
Single-ended to VCC; ORADJ0 = ORADJ1 = 0
20
25
30
Ω
Digital input current
SCK, SDA, pullup to VCC
360
470
µA
Digital input current
DIS, pullup to VCC
360
470
µA
VOH
Digital output high
voltage
FLT, pullup to VCC, ISOURCE = 50 µA
VOL
Digital output low
voltage
FLT, pullup to VCC, ISINK = 350 µA
IBIAS-MIN
Minimum bias current
See
IBIAS-MAX
Maximum bias
current
Sink or source. DAC set to maximum, open and
closed loop
IBIAS-DIS
Bias current during
disable
Output off (DIS = HIGH), IMOD = 30 mA, IBIAS = 30 mA
VPD
BIASPOL = 0 (sink)
Temperature sensor
accuracy
With one-point external midscale calibration
Photodiode reverse
bias voltage
APC active, IPD = max
Photodiode fault
current level
Percent of target IPD
BIASPOL = 1 (source)
VMONBFLT
VMONPFLT
(1)
(2)
6
1.3
2.3
V
150
%
15
IMONP / IPD with control bit PDRNG = 01
20
25
30
IMONP / IPD with control bit PDRNG = 00
40
50
60
Bias current DMI
accuracy
Bias current ≥ 20 mA
–10
+10
0.9
1.0
1.1
1.25
1.43
1.61
±10
–2.5
VCC voltage level which triggers power-on reset
V
°C
12.5
BIASPOL = 1, IMONB / IBIAS (nominal 1 / 70 = 1.43%)
µA
±3
10
BIASPOL = 0, IMONB / IBIAS (nominal 1 / 100 = 1%)
mA
dB
IMONP / IPD with control bit PDRNG = 1X
Bias current monitor
ratio
V
mA
VCC – 0.8
(2)
With external midscale calibration
PD current > 200 µA, 400 µA, and 800 µA for
PDRNG = 00, 01, and 1X, respectively
VCC reset threshold
voltage hysteresis
100
0.8
Power supply monitor With external midscale calibration
accuracy
RSTHYS
88
±0.5
Monitor diode DMI
accuracy
VCC-
0.4
100
Bias pin compliance
voltage
VCC reset threshold
voltage
V
5
APC active
VCC-RST
2.3
(1)
Average power
stability
Photodiode current
monitor ratio
44
2.5
%
%
%
%
+2.5
%
2.8
V
100
mV
Fault voltage at
MONB
Fault occurs if voltage at MONB exceeds value
1.1
1.16
1.24
V
Fault voltage at
MONP
MONPFLT = 1, Fault occurs if voltage at MONP
exceeds value
1.1
1.16
1.24
V
The bias current can be set below the specified minimum according to the corresponding register setting; however, in closed-loop
operation, settings below the specified value may trigger a fault.
Assured by simulation over process, supply and temperature variation
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AC ELECTRICAL CHARACTERISTICS
Over recommended operating conditions with 25-Ω, single-ended output load, open-loop operation, IMOD = 30 mA,
IBIAS = 30 mA, and RRZTC = 28.7 kΩ, unless otherwise noted. Typical operating condition is at VCC = 3.3 V and TA = +25°C
PARAMETER
TEST CONDITION
MIN
NOM
MAX
UNIT
Differential input return
gain
0.01 GHz < f ≤ 5 GHz
–15
5 GHz < f < 11.1 GHz
–8
Differential to common
mode conversion gain
0.01 GHz < f < 11.1 GHz
–15
SDD22
Differential output
return gain
0.01 GHz < f ≤ 5 GHz
–20
5 GHz < f < 11.1 GHz
–12
tR-OUT
Output rise time
20% – 80%, tR-IN < 40 ps, 25-Ω load, singleended
23
35
ps
tF-OUT
Output fall time
20% – 80%, tF-IN < 40 ps, 25-Ω load, singleended
23
35
ps
IMOD-MIN
Minimum modulation
current
5
mA
IMOD-MAX
Maximum modulation
current
AC-coupled outputs, 10-Ω differential load,
CPENA = 1
IMOD-STEP
Modulation current
step size
10-bit register
SDD11
SCD11
DJ
Deterministic output
jitter
RJ
Random output jitter
τAPC
APC time constant
TON
µA
7
0.2
Rising edge of DIS to IBIAS ≤ 0.1 × IBIAS-
Disable negate time
Falling edge of DIS to IBIAS ≥ 0.9 × IBIAS-
NOMINAL
0.05
(1)
(1)
TINIT1
Power-on to initialize
Power-on to registers ready to be loaded
TINIT2
Initialize to transmit
Register load STOP command to part ready
to transmit valid data (1)
TRESET
DIS pulse width
Time DIS must held high to reset part (1)
TFAULT
Fault assert time
Time from fault condition to FLT high (1)
10
psP-P
0.6
psRMS
120
30
NOMINAL
(1)
86
EQENA = 1, PRBS7 + 72 ones + PRBS7 +
72 zeros at 11.3 Gbps, maximum
equalization with 6-in. transmission line at the
input, 400 mVpp at input to transmission line
Transmitter disable
time
dB
mA
5
CAPC 0.01 µF, IPD = 100 µA, PD-coupling
ratio, CR = 40 (1)
dB
85
EQENA = 0, PRBS7 + 72 ones + PRBS7 +
72 zeros at 11.3 Gbps, 150 mVpp, 600
mVpp, 1200 mVpp differential-input voltage
Cross-point control
range
TOFF
75
dB
1
µs
70
%
5
µs
1
ms
10
ms
2
ms
50
µs
100
ns
Assured by simulation over process, supply and temperature variation
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DETAILED DESCRIPTION
EQUALIZER
The data signal is applied to an input equalizer by means of the input signal pins DIN+ and DIN–, which provide
on-chip differential 100-Ω line-termination. The equalizer is enabled by setting EQENA = 1 (bit 1 of register 0).
Equalization of up to 150 mm (6 in.) of microstrip or stripline transmission line on FR4-printed circuit boards is
achievable. The amount of equalization is digitally controlled by the 2-wire interface and control logic block and is
dependent on the register settings EQADJ[0..7] (of register 6). To turn off and bypass the equalizer, set EQENA
= 0; this reduces the supply current. For details about the equalizer settings, see Table 5.
LIMITER
By limiting the output signal of the equalizer to a fixed value, the limiter removes any overshoot after the input
equalization and provides the input signal for the output driver. Make adjustments to the limiter bias current and
emitter follower current to trade off the rise and fall times and supply current. Adjust the limiter bias current
through LIMCSGN (bit 7 of register 9) and LIMC[0..2] (bits 4, 5, and 6 of register 9). Adjust the emitter follower
current through EFCSGN (bit 3 of register 9) and EFC[0..2] (bits 0, 1, and 2 of register 9).
HIGH-SPEED OUTPUT DRIVER
The modulation current sinks from the common-emitter node of the limiting-output driver-differential pair by
means of a modulation-current generator, which is digitally controlled by the 2-wire serial interface.
The collector nodes of the output stages connect to output pins MOD+ and MOD–. The collectors have internal
25-Ω back termination resistors to VCC. However, the resistance adjusts higher through ORADJ[0..1] (bits 3 and
4 of register 8). Setting ORADJ to 00, results in the lowest-output termination resistance and setting the bits to
11, results in the highest-output resistance. The outputs are optimized to drive a 25-Ω, single-ended load and
obtain the maximum modulation current of 85 mA. AC coupling and inductive pullups to VCC are required and
CPENA (bit 4 of register 1) should be set to 1.
To improve the eye-mask margin, output de-emphasis is applied by adjusting DE[0..2] (bits 0 to 2 of register 8).
The polarity of the output pins can be inverted by setting the output polarity switch bit, POL (bit 2 of register 0) to
1.
MODULATION CURRENT GENERATOR
The modulation current generator provides the current for the current modulator described previously. The circuit
is digitally controlled by the 2-wire interface block.
A 10-bit-wide control bus, MODC[0..9] (registers 2 and 3), sets the desired modulation current.
The modulation current can be disabled by setting the DIS input pin to a high level or setting ENA = 0 (bit 7 of
register 0). The modulation current is also disabled in a fault condition, if the internal fault detection enable
register flag FLTEN is set to 1 (bit 3 of register 0). To reduce the disable time, only the output stage can be
disabled by setting DISMODE = 1 (bit 1 of register 1).
DC OFFSET CANCELLATION AND CROSS-POINT CONTROL
The ONET1151L device has DC offset cancellation by default to compensate for internal offset voltages. To
adjust the eye-crossing point, set CPENA = 1 (bit 4 of register 1) and disable the offset cancellation by setting
OCDIS = 1 (bit 3 of register 1). Note that setting OCDIS = 1 with CPENA = 0 is an invalid state and results in the
modulation current being disabled. The crossing point can be moved toward the one level by setting CPSGN = 1
(bit 7 of register 7) and toward the zero level by setting CPSGN = 0. The percentage of shift depends upon the
register settings CPADJ[0..6] (register 7) and the cross-point adjustment range bits CPRNG[0..1] (register 1).
Setting CPRNG1 = 0 and CPRNG0 = 0 results in minimum adjustment capability and setting CPRNG1 = 1 and
CPRNG0 = 1 results in maximum adjustment capability.
In addition, the modulation current capability is increased by setting CPENA = 1 with or without the offset
cancellation being disabled. Table 2 provides a truth table for the various options.
8
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Table 2. ADC Selection Bits and the Monitored Parameter
CPENA (Bit 4, Register
1)
OCDIS (Bit 3, Register 1)
Cross-Point Adjust
Offset Cancellation
High Modulation Current
0
0
Disabled
Enabled
Disabled
0
1
Invalid
Invalid
Invalid
1
0
Disabled
Enabled
Enabled
1
1
Enabled
Disabled
Enabled
BIAS CURRENT GENERATION AND APC LOOP
The bias current generation and APC loop are controlled by the 2-wire interface. In open-loop operation, selected
by setting OLENA = 1 (bit 4 of register 0), the bias current is set directly by the 10-bit-wide control word
BIASC[0..9] (registers 4 and 5). In automatic power control mode, selected by setting OLENA = 0, the bias
current depends on the register settings BIASC[0..9] and the coupling ratio (CR) between the laser bias current
and the photodiode current, CR = IBIAS / IPD. If the photodiode anode is connected to the PD pin (PD pin is
sinking current), set PDPOL = 1 (bit 0 of register 0), and if the photodiode cathode is connected to the PD pin
(PD pin is sourcing current), set PDPOL = 0.
Three photodiode current ranges are selected by means of the PDRNG[0..1] bits (register 0). Select the
photodiode range to keep the laser bias control DAC, BIASC[0..9], close to the center of its range. This range
keeps the laser bias current set-point resolution high. For details regarding the bias current setting in open-loop
mode, as well as in closed-loop mode, see Table 5.
The ONET1151L device can source or sink the bias current. For the BIAS pin to act as a source, set BIASPOL =
1 (bit 2 of register 1) and for the BIAS pin to act as a sink, set BIASPOL = 0.
The bias current in sink mode is monitored using a current mirror with a gain equal to 1/100 and in source mode
with a gain equal to 1/70. By connecting a resistor between MONB and GND, the bias current can be monitored
as a voltage across the resistor. A low temperature coefficient precision resistor should be used. The bias current
can also be monitored as a 10 bit unsigned digital word through the 2-wire interface by setting DMONB = 1 (bit 0
of register 10) and removing the resistor to ground.
ANALOG REFERENCE
The ONET1151L laser driver is supplied by a single 3.3-V ±10% supply voltage connected to the VCC pins. This
voltage is referred to GND and can be monitored as a 10-bit unsigned digital word through the 2-wire interface.
On-chip band-gap voltage circuitry generates a reference voltage, independent of the supply voltage, from which
all other internally required voltages and bias currents are derived.
An external zero temperature coefficient resistor must be connected from the RZTC pin of the device to ground
(GND). This resistor is used to generate a precise, zero TC current, which is required as a reference current for
the on-chip DACs.
To minimize the module component count, the ONET1151L device provides an on-chip temperature sensor. The
temperature can be monitored as a 10-bit unsigned digital word through the 2-wire interface.
POWER-ON RESET
The ONE1151L device has power-on reset circuitry, which ensures that registers are reset to zero during startup. After the power on to initialize time (tINIT1), the internal registers are ready to be loaded. The device is ready
to transmit data after the initialize-to-transmit time (tINIT2), assuming that the chip enable bit ENA is set to 1 and
the disable pin DIS is low. The DIS pin has an internal 10-kΩ pullup resistor, so the pin must be pulled low to
enable the outputs.
The ONET1151L device can be disabled using either the ENA control register bit or the disable pin DIS. In both
cases, the internal registers are not reset. After the disable pin DIS is set low and/or the enable bit ENA is reset
to 1, the device returns to its previous output settings.
To reduce the disable time, only the output stage can be disabled by setting DISMODE = 1 (bit 1 of register 1).
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ANALOG-TO-DIGITAL CONVERTER
The ONE1151L device has an internal 10-bit ADC that converts the analog monitors for temperature, powersupply voltage, bias current, and photodiode current into a 10-bit unsigned digital word. The first 8 most
significant bits (MSBs) are available in register 14 and the 2 least significant bits (LSBs) are available in register
15. Depending on the accuracy required, 8 or 10 bits can be read. However, to read the two registers, two
separate read commands must be sent due to the architecture of the 2-wire interface.
The ADC is enabled by default, and to monitor a particular parameter, select the parameter with ADCSEL[0..1]
(bits 0 and 1 of register 13). Table 3 shows the ADCSEL bits and the monitored parameter.
Table 3. ADC Selection Bits and the Monitored Parameter
ADCSEL1
ADCSEL0
Monitored Parameter
0
0
Temperature
0
1
Supply voltage
1
0
Photodiode current
1
1
Bias current
To digitally monitor the photodiode current, ensure that DMONP = 1 (bit 1 of register 10) and a resistor is not
connected to the MONP pin. To digitally monitor the bias current, ensure that DMONB = 1 (bit 0 of register 10)
and a resistor is not connected to the MONB pin. If the ADC is not used to monitor the various parameters, then
it can be disabled by setting ADCDIS = 1 (bit 7 of register 13) and OSCDIS = 1 (bit 6 of register 13).
The recommended procedure for reading the ADC follows:
1. Disable the ADC (set bit 7 of register 13 to 1).
2. Set the desired ADC mode (set bits 0 and 1 of register 13 per Table 3).
3. Enable the ADC (set bit 7 of register 13 to 0).
4. Wait 500 µs.
5. Disable the ADC (set bit 7 of register 13 to 1).
6. Read the ADC conversion result from register 14 (MSB) and register 15 (LSB).
Convert the digital word read from the ADC to its analog equivalent through the following formulas.
Temperature without a midpoint calibration:
Temperature (qC) =
ADCx 264
6
(1)
Temperature with a midpoint calibration:
Temperature (qC)
T_cal(qC)
273 u
ADCx + 1362
ADC_cal + 1362
273
(2)
Power supply voltage:
Power supply voltage (V) =
2.25 u
ADCx + 1380
1409
(3)
Photodiode current monitor:
IPD($ u $'&x IRU3'51*
IPD($ u $'&x IRU3'51*
IPD($ u $'&x IRU3'51*x
(4)
(5)
(6)
Bias current monitor source mode:
IBIAS (mA) = 0.12 u ADCx
(7)
Bias current monitor sink mode:
IBIAS (mA) = 0.19 u ADCx
10
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where
•
•
•
ADCx = the decimal value read from the ADC
T_cal = the calibration temperature
ADC_cal = the decimal value read from the ADC at the calibration temperature
(8)
For the photodiode and bias current monitors, a nonzero current must be applied to the ADC in order to read
back a valid result. For the cases when the bias current is set to zero, the DIS pin is set high or the ENA bit is set
to 0, bias current is not applied to the ADC and the digital reading is not valid.
2-WIRE INTERFACE AND CONTROL LOGIC
The ONET1151L device uses a 2-wire serial interface for digital control. The two circuit inputs, SDA and SCK,
are driven, respectively, by the serial data and serial clock from a microprocessor, for example. The SDA and
SCK pins have internal 10-kΩ pullups to VCC. If a common interface is used to control multiple parts, the internal
pullups can be switched to 40 kΩ by setting the TWITERM bit to 1 (bit 0 of register 1). The internal pullups
automatically switch to 40 kΩ, if the slave address is changed from its default value using the ADR0 or ADR1
pins.
The 2-wire interface allows write access to the internal memory map to modify control registers and read access
to read the control signals. The ONET1151L device is a slave device, which means that it cannot initiate a
transmission itself. The ONET1151L device always relies on the availability of the SCK signal for the duration of
the transmission. The master device provides the clock signal as well as the START and STOP commands. The
protocol for a data transmission is as follows:
1. START command
2. 7-bit slave address (0001000) followed by an eighth bit, which is the data direction bit (R/W). 0 indicates a
Write and 1 indicates a Read.
3. 8-bit register address
4. 8-bit register data word
5. STOP command
The first 2 bits of the slave address can be changed to 1 by grounding the ADR0 and ADR1 pins.
Regarding timing, the ONET1151L device is I2C compatible. Figure 2 shows the typical timing. Figure 3 shows a
complete data transfer. Table 4 lists parameters for Figure 2.
Descriptions of various events on the 2-wire interface follow:
Bus idle: Both SDA and SCK lines remain High.
Start data transfer: A change in the state of the SDA line, from High to Low, while the SCK line is High, defines
a Start condition (S). Each data transfer initiates with a Start condition.
Stop data transfer: A change in the state of the SDA line from Low to High while the SCK line is High, defines a
Stop condition (P). Each data transfer is terminated with a Stop condition. However, if the master still wishes to
communicate on the bus, it can generate a repeated Start condition and address another slave without first
generating a Stop condition.
Data transfer: Only one data byte can be transferred between a Start and a Stop condition. The receiver
acknowledges the transfer of data.
Acknowledge: Each receiving device, when addressed, is obliged to generate an acknowledge bit. The
transmitter releases the SDA line and a device that acknowledges must pull down the SDA line during the
acknowledge clock pulse so that the SDA line is stable Low during the High period of the acknowledge clock
pulse. Setup and hold times must be taken into account. When a slave-receiver does not acknowledge the slave
address, the data line must be left High by the slave. The master can then generate a Stop condition to abort the
transfer. If the slave-receiver does acknowledge the slave address, but some time later in the transfer cannot
receive any more data bytes, the master must abort the transfer. The slave indicates by generating no
acknowledgment on the first byte to follow. The slave leaves the data line High, and the master generates the
Stop condition.
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SDA
tBUF
SCK
P
tLOW
tR
tHIGH
tF
tHDSTA
S
S
tHDSTA
tHDDAT
tSUDAT
P
tSUSTA
tSUSTO
Figure 2. I2C Timing Diagram
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Table 4. Timing Diagram Definitions
PARAMETER
MIN
MAX
UNIT
400
kHz
fSCK
SCK clock frequency
tBUF
Bus free time between Start and Stop conditions
1.3
μs
tHDSTA
Hold time after repeated Start condition. After this period,
the first clock pulse is generated
0.6
μs
tLOW
Low period of the SCK clock
1.3
μs
tHIGH
High period of the SCK clock
0.6
μs
tSUSTA
Setup time for a repeated Start condition
0.6
μs
tHDDAT
Data hold time
0
μs
tSUDAT
Data setup time
tR
Rise time of both SDA and SCK signals
300
tF
Fall time of both SDA and SCK signals
300
tSUSTO
Setup time for Stop condition
100
ns
ns
ns
μs
0.6
Write Sequence
1
7
1
1
8
1
8
1
1
S
Slave Address
Wr
A
Register Address
A
Data Byte
A
P
Read Sequence
1
7
1
1
8
1
1
7
1
1
8
1
1
S
Slave Address
Wr
A
Register Address
A
S
Slave Address
Rd
A
Data Byte
N
P
Legend
S
Start Condition
Wr
Write Bit (bit value = 0)
Rd
Read Bit (bit value = 1)
A
Acknowledge
N
Not Acknowledged
P
Stop Condition
Figure 3. Programming Sequence
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REGISTER MAPPING
Figure 4 through Figure 19 show the register mapping for register addresses 0 (0x00) through 15 (0x0F),
respectively.
bit 7
ENA
bit 6
PDRNG1
bit 5
PDRNG0
register address 0 (0x00)
bit 4
bit 3
OLENA
FLTEN
bit 2
POL
bit 1
EQENA
bit 0
PDPOL
bit 1
DISMODE
bit 0
TWITERM
bit 1
MODC1
bit 0
MODC0
bit 1
MODC3
bit 0
MODC2
bit 1
BIASC1
bit 0
BIASC0
bit 4
BIASC3
bit 3
BIASC2
bit 1
EQADJ1
bit 0
EQADJ0
bit 1
CPADJ1
bit 0
CPADJ0
Figure 4. Register 0 (0x00) Mapping – Control Settings
bit 7
CPTC
bit 6
CPRNG1
bit 5
CPRNG0
register address 1 (0x01)
bit 4
bit 3
CPENA
OCDIS
bit 2
BIASPOL
Figure 5. Register 1 (0x01) Mapping – Control Settings
bit 7
–
bit 6
–
bit 5
–
register address 2 (0x02)
bit 4
bit 3
–
–
bit 2
–
Figure 6. Register 2 (0x02) Mapping – Modulation Current
bit 7
MODC9
bit 6
MODC8
bit 5
MODC7
register address 3 (0x03)
bit 4
bit 3
MODC6
MODC5
bit 2
MODC4
Figure 7. Register 3 (0x03) Mapping – Modulation Current
bit 7
–
bit 6
–
bit 5
–
register address 4 (0x04)
bit 4
bit 3
–
–
bit 2
–
Figure 8. Register 4 (0x04) Mapping – Bias Current
bit 7
BIASC9
bit 6
BIASC8
bit 5
BIASC7
register address 5 (0x05)
bit 7
bit 6
BIASC6
BIASC5
bit 5
BIASC4
Figure 9. Register 5 (0x05) Mapping – Bias Current
bit 7
EQADJ7
bit 6
EQADJ6
bit 5
EQADJ5
register address 6 (0x06)
bit 4
bit 3
EQADJ4
EQADJ3
bit 2
EQADJ2
Figure 10. Register 6 (0x06) Mapping – Equalizer Adjust
bit 7
CPSGN
bit 6
CPADJ6
bit 5
CPADJ5
register address 7 (0x07)
bit 4
bit 3
CPADJ4
CPADJ3
bit 2
CPADJ2
Figure 11. Register 7 (0x07) Mapping – Cross-Point Adjust
14
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bit 7
LOWGAIN
SLLSEI7 – DECEMBER 2013
bit 6
–
bit 5
–
register address 8 (0x08)
bit 4
bit 3
ORADJ1
ORADJ0
bit 2
DE2
bit 1
DE1
bit 0
DE0
bit 1
EFC1
bit 0
EFC0
Figure 12. Register 8 (0x08) Mapping – Output Adjustments
bit 7
LIMCSGN
bit 6
LMC2
bit 5
LIMC1
register address 9 (0x09)
bit 4
bit 3
LIMC0
EFCSGN
bit 2
EFC2
Figure 13. Register 9 (0x09) Mapping – Limiter Bias Current Adjust
bit 7
–
bit 6
–
bit 5
–
register address 10 (0x0A)
bit 4
bit 3
–
–
bit 2
MONPFLT
bit 1
DMONP
bit 0
DMONB
bit 1
BMF1
bit 0
BMF0
Figure 14. Register 10 (0x0A) Mapping – Monitor Settings
bit 7
BMF7
bit 6
BMF6
bit 5
BMF5
register address 11 (0x0B)
bit 4
bit 3
BMF4
BMF3
bit 2
BMF2
Figure 15. Register 11 (0x0B) Mapping – Bias Monitor Fault Settings
bit 7
PMF7
bit 6
PMF6
bit 5
PMF5
register address 12 (0x0C)
bit 4
bit 3
PMF4
PMF3
bit 2
PMF2
bit 1
PMF1
bit 0
PMF0
Figure 16. Register 12 (0x0C) Mapping – Power Monitor Fault Settings
bit 7
ADCDIS
bit 6
OSCDIS
bit 5
–
register address 13 (0x0D)
bit 4
bit 3
–
–
bit 2
–
bit 1
ADCSEL1
bit 0
ADCSEL0
bit 1
ADC3
bit 0
ADC2
Figure 17. Register 13 (0x0D) Mapping – ADC Settings
bit 7
ADC9
bit 6
ADC8
bit 5
ADC7
register address 14 (0x0E)
bit 4
bit 3
ADC6
ADC5
bit 2
ADC4
Figure 18. Register 14 (0x0E) Mapping – ADC Output (Read Only)
bit 7
–
bit 6
–
bit 5
–
register address 15 (0x0F)
bit 4
bit 3
–
–
bit 2
–
bit 1
ADC1
bit 0
ADC0
Figure 19. Register 15 (0x0F) Mapping – ADC Output (Read Only)
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Table 5 describes the circuit functionality based on the register settings.
Table 5. Register Functionality
Register
0
1
2
3
16
Bit
Symbol
Function
7
ENA
Enable chip bit
1 = Chip enabled, can be toggled low to reset a fault condition.
0 = Chip disabled
6
5
PDRNG1
PDRNG0
Photodiode current range bits
1X: up to 3080-µA / 3-µA resolution
01: up to 1540-µA / 1.5-µA resolution
00: up to 770-μA / 0.75-μA resolution
4
OLENA
Open-loop enable bit
1 = Open-loop bias current control
0 = Closed-loop bias current control
3
FLTEN
Fault detection enable bit
1 = Fault detection on
0 = Fault detection off
2
POL
Output polarity switch bit
1: pin 22 = OUT– and pin 21 = OUT+
0: pin 22 = OUT+ and pin 21 = OUT–
1
EQENA
Equalizer enable bit
1 = Equalizer is enabled
0 = Equalizer is disabled and bypassed
0
PDPOL
Photodiode polarity bit
1 = Photodiode cathode connected to VCC
0 = Photodiode anode connected to GND
7
CPTC
Cross-point temperature coefficient adjustment bit
1 = Cross-point temperature coefficient is enabled
0 = Cross-point temperature coefficient is disabled
6
5
CPRNG1
CPRNG0
Cross-point adjustment range bits
Minimum adjustment range for 00
Maximum adjustment range for 11
4
CPENA
Cross-point adjustment enable bit
1 = Cross-point adjustment is enabled. Setting to 1 with OCDIS = 0 or 1 increases the modulation current.
0 = Cross-point adjustment is disabled
3
OCDIS
Offset cancellation disable bit
1 = DC offset cancellation is disabled. Do not set to 1 with CPENA set to 0.
0 = DC offset cancellation is enabled
2
BIASPOL
Bias current polarity bit
1 = Bias pin sources current
0 = Bias pin sinks current
1
DISMODE
Disable mode setting bit
1 = Only the output stage is disabled (fast-disable mode)
0 = Major parts of the signal path are disabled
0
TWITERM
2-wire interface input termination select bit
1 = 40 kΩ selected
0 = 10 kΩ selected
1
MODC1
0
MODC0
7
MODC9
6
MODC8
5
MODC7
4
MODC6
3
MODC5
2
MODC4
1
MODC3
0
MODC2
Modulation current setting: sets the output voltage
Modulation current : 85-mA or 86-μA steps
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Table 5. Register Functionality (continued)
Register
4
5
6
7
Bit
Symbol
BIASC1
0
BIASC0
7
BIASC9
6
BIASC8
5
BIASC7
4
BIASC6
3
BIASC5
2
BIASC4
1
BIASC3
0
BIASC2
7
EQADJ7
6
EQADJ6
5
EQADJ5
4
EQADJ4
3
EQADJ3
2
EQADJ2
1
EQADJ1
0
EQADJ0
7
CPSGN
6
CPADJ6
5
CPADJ5
4
CPADJ4
3
CPADJ3
2
CPADJ2
1
CPADJ1
0
CPADJ0
7
LOWGAIN
6
–
5
–
4
3
ORADJ1
ORADJ0
Output resistance adjustment setting
00 = Lowest resistance
11 = Highest resistance
2
1
0
DE2
DE1
DE0
Output De-emphasis adjustment setting
000 = No de-emphasis
111 = Maximum de-emphasis
7
LIMCSGN
Limiter bias current sign bit
1 = Decrease limiter bias current
0 = Increase limiter bias current
6
5
4
LIMC2
LIMC1
LIMC0
Limiter bias current selection bits
000 = No change
111 = Maximum current change
3
EFCSGN
Emitter follower sign bit
1 = Decrease emitter follower current
0 = Increase emitter follower current
2
1
0
EFC2
EFC1
EFC0
Emitter follower current selection bits
000 = No change
111 = Maximum current change
8
9
Function
1
Closed loop (APC):
Coupling ratio CR = IBIAS / IPD, BIASC = 0..1023, IBIAS ≤ 100 mA:
PDRNG = 00 (see above); IBIAS = 0.75 µA × CR × BIASC
PDRNG = 01 (see above); IBIAS = 1.5 µA × CR × BIASC
PDRNG = 1X (see above); IBIAS = 3 µA × CR × BIASC
Open loop:
IBIAS = 102 µA × BIASC
Equalizer adjustment setting
EQENA = 0 (see above)
Equalizer is turned off and bypassed
EQENA = 1 (see above)
Maximum equalization for 00000000
Minimum equalization for 11111111
Eye cross-point adjustment setting
CPSGN = 1 (positive shift)
Maximum shift for 1111111
Minimum shift for 0000000
CPSGN = 0 (negative shift)
Maximum shift for 1111111
Minimum shift for 0000000
Path-gain control bit
1 = Half gain used to reduce power if cross-point adjustment is not used
0 = Full gain
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Table 5. Register Functionality (continued)
Register
10
11
12
13
18
Bit
Symbol
Function
7
–
6
–
5
–
4
–
3
–
2
MONPFLT
Analog photodiode current monitor fault trigger bit
1 = Fault trigger on MONP pin is enabled
0 = Fault trigger on MONP pin is disabled
1
DMONP
Digital photodiode current monitor selection bit (MONP)
1 = Digital photodiode monitor is active (no external resistor is needed)
0 = Analog photodiode monitor is active (external resistor is required)
0
DMONB
Digital bias current monitor selection bit (MONB)
1 = Digital bias current monitor is active (no external resistor is needed)
0 = Analog bias current monitor is active (external resistor is required)
7
BMF7
6
BMF6
5
BMF5
4
BMF4
3
BMF3
2
BMF2
1
BMF1
0
BMF0
7
PMF7
6
PMF6
5
PMF5
4
PMF4
3
PMF3
2
PMF2
1
PMF1
0
PMF0
7
ADCDIS
ADC disable bit
1 = ADC disabled
0 = ADC enabled
6
OSCDIS
ADC oscillator bit
1 = Oscillator disabled
0 = Oscillator enabled
5
–
4
–
3
–
2
–
1
0
ADCSEL1
ADCSEL0
Bias current monitor fault threshold
With DMONB = 1
Register sets the value of the bias current that will trigger a fault.
The external resistor on the MONB pin must be removed to use this feature.
Power monitor fault threshold
With DMONP = 1
Register sets the value of the photodiode current that will trigger a fault.
The external resistor on the MONP pin must be removed to use this feature.
ADC input selection bits
00 selects the temperature sensor
01 selects the power supply monitor
10 selects MONP
11 selects MONB
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Table 5. Register Functionality (continued)
Register
14
15
Bit
Symbol
7
ADC9 (MSB)
6
ADC8
5
ADC7
4
ADC6
3
ADC5
2
ADC4
1
ADC3
0
ADC2
7
–
6
–
5
–
4
–
3
–
2
–
1
ADC1
0
ADC0 (LSB)
Function
Digital representation of the ADC input source (read only)
Digital representation of the ADC input source (read only)
LASER SAFETY FEATURES AND FAULT RECOVERY PROCEDURE
The ONET1151L device provides built-in laser safety features. The following fault conditions are detected:
• Voltage at MONB exceeds the voltage at RZTC (1.16 V), or alternately, if DMONB = 1 and the bias current
exceeds the bias current monitor fault threshold set by BMF[0..7] (register 11). When using the digital
monitor, the resistor to ground must be removed.
• Voltage at MONP exceeds the voltage at RZTC (1.16 V) and the analog photodiode current monitor fault
trigger bit, MONPFLT (bit 2 of register 10), is set to 1. Alternately, a fault can be triggered if DMONP = 1 and
the bias current exceeds the bias current monitor fault threshold set by PMF[0..7] (register 12). When using
the digital monitor, the resistor to ground must be removed.
• Photodiode current exceeds 150% of its set value.
• Bias control DAC drops in value by more than 50% in one step.
If one or more fault conditions occur, and the fault enable bit FLTEN is set to 1, the ONET1151L device responds
by:
1. Setting the bias current to 0
2. Setting the modulation current to 0
3. Asserting and latching the FLT pin
Fault recovery is achieved by performing the following procedure:
1. The disable pin DIS, or the internal enable control bit ENA, or both, are toggled for at least the fault latch
reset time.
2. The FLT pin deasserts while the disable pin DIS is asserted or the enable bit ENA is deasserted.
3. If the fault condition is no longer present, the device returns to typical operation with its previous output
settings, after the disable negate time.
4. If the fault condition is still present, FLT reasserts once DIS is set to a low level and the part does not return
to typical operation.
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APPLICATIONS INFORMATION
Figure 20 shows a typical application circuit using the ONET1151L device with a differentially driven laser. The
laser driver is controlled through the 2-wire interface SDA and SCK by a microcontroller.
DIS
VCC
SDK
0.1 F
PD
ADR0
ADR1
DIS
SCK
SDA
SDA
FLT
FLT
C1
0.1 F
VCC
GND
MOD-
ONET1151L
DIN±
DINC2
0.1 F
0.1 F
MOD-
DIN+
DIN+
0.1 F
GND
MOD+
Monitor
Photodiode
0.1 F
BIAS
GND
VCC
VCC
COMP
MONP
RZTC
MONB
LD
Optional
MOD+
0.1 F
RZTC
28.7 k
0.1 F
0.1 F
MONB
RMONB
1.2 k
MONP
RMONP
5 k
CCOMP
0.01 F
Figure 20. AC-Coupled Differential Drive
LAYOUT GUIDELINES
For optimum performance, use 50-Ω transmission lines (100-Ω differential) for connecting the signal source to
the DIN+ and DIN– pins and 25-Ω transmission lines (50-Ω differential) for connecting the modulation current
outputs, MOD+ and MOD-, to the laser. The length of the transmission lines should be kept as short as possible
to reduce loss and pattern-dependent jitter. TI recommends assembling the series matching resistor as close as
possible to the TOSA, if required.
20
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TYPICAL OPERATION CHARACTERISTICS
Typical operating condition is at VCC = +3.3 V, TA = +25°C, IBIASC = 30 mA, IMODC = 30 mA, VIN = 600 mVpp (unless otherwise
noted).
DETERMINISTIC JITTER
vs
MODULATION CURRENT
DETERMINISTIC JITTER
vs
TEMPERATURE
8.00
Deterministic Jitter (pspp)
Deterministic Jitter (pspp)
8
6
4
2
4.00
2.00
0.00
0
0
200
400
600
800
1000
Modulation Current Register Setting ± Decimal
-40
1200
0
20
40
Figure 21.
Figure 22.
RANDOM JITTER
vs
MODULATION CURRENT
RANDOM JITTER
vs
TEMPERATURE
0.4
0.4
0.3
0.3
0.2
0.1
60
80
TA ± Free-Air Temperature (C)
0.0
100
C002
0.2
0.1
0.0
0
200
400
600
800
1000
Modulation Current Register Setting ± Decimal
1200
±40
±20
0
20
40
60
C003
Figure 23.
Figure 24.
RISE-TIME AND FALL-TIME
vs
MODULATION CURRENT
RISE-TIME AND FALL-TIME
vs
TEMPERATURE
35
35
30
30
25
20
15
10
5
80
TA ± Free-Air Temperature (C)
Transition Time (ps)
Transition Time (ps)
-20
C001
Random Jitter (psrms)
Random Jitter (psrms)
6.00
100
C004
25
20
15
10
5
0
0
0
200
400
600
800
1000
Modulation Current Register Setting ± Decimal
1200
±40
±20
0
20
40
60
80
C005
100
C006
TA ± Free-Air Temperature (C)
Figure 25.
Figure 26.
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ONET1151L
SLLSEI7 – DECEMBER 2013
www.ti.com
TYPICAL OPERATION CHARACTERISTICS (continued)
Typical operating condition is at VCC = +3.3 V, TA = +25°C, IBIASC = 30 mA, IMODC = 30 mA, VIN = 600 mVpp (unless otherwise
noted).
BIAS CURRENT IN OPEN LOOP MODE
vs
BIASC REGISTER SETTING
BIAS-MONITOR CURRENT IMONB
vs
BIAS CURRENT
1.2
120
Bias Monitor Current (mA)
Sink OL Bias Current (mA)
1.1
100
80
60
40
20
1.0
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
0.0
0
200
400
600
800
1000
Bias Current Register Setting (Decimal)
0
1200
40
60
80
Bias Current (mA)
C007
100
C008
Figure 27.
Figure 28.
PHOTODIODE-MONITOR CURRENT IMONP
vs
PD CURRENT, PDRNG = 01
MODULATION CURRENT
vs
MODC REGISTER SETTING
100
0.7
90
0.6
Modulation Current (mA)
Photodiode Monitor Current (mA)
20
0.5
0.4
0.3
0.2
0.1
80
70
60
50
40
30
20
10
0.0
0
0.0
0.5
1.0
1.5
2.0
2.5
Photodiode Current (mA)
0
200
400
600
800
1000
Modulation Current Register Setting (Decimal)
C009
Figure 29.
1200
C010
Figure 30.
SUPPLY CURRENT
vs
TEMPERATURE
150
Supply Current (mA)
140
130
120
110
100
±40
±20
0
20
40
60
TA ± Free-Air Temperature (C)
Figure 31.
22
80
14.8 ps/Div
100
C011
Figure 32. Eye-Diagram at 11.3 Gbps IMOD = 20 mA,
EQENA = 0
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ONET1151L
www.ti.com
SLLSEI7 – DECEMBER 2013
TYPICAL OPERATION CHARACTERISTICS (continued)
Typical operating condition is at VCC = +3.3 V, TA = +25°C, IBIASC = 30 mA, IMODC = 30 mA, VIN = 600 mVpp (unless otherwise
noted).
14.8 ps/Div
Figure 33. Eye-Diagram at 11.3 Gbps IMOD = 40 mA,
EQENA = 0
14.8 ps/Div
Figure 34. Eye-Diagram at 11.3 Gbps PRBS-31 Pattern,
IMOD= 60 mA, EQENA = 0
14.8 ps/Div
Figure 35. Eye-Diagram at 11.3 Gbps IMOD = 40 mA, EQENA = 1, 12 in. of FR4 at Inputs
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23
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
ONET1151LRGER
ACTIVE
VQFN
RGE
24
3000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 100
ONET
1151L
ONET1151LRGET
ACTIVE
VQFN
RGE
24
250
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 100
ONET
1151L
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of