LMH6525 [TI]

具有双输出的四通道激光二极管驱动器;


型号：	LMH6525
厂家：	TEXAS INSTRUMENTS
描述：	具有双输出的四通道激光二极管驱动器驱动二极管激光二极管驱动器
文件：	总25页 (文件大小：1278K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

LMH6525/LMH6526 Four–Channel Laser Diode Driver with Dual Output

Check for Samples: LMH6525, LMH6526

FEATURES

•

LMH6525 has Differential Enable Oscillator

Inputs

•

Fast Switching: Rise and Fall Times: 0.6/1.0

ns.

LMH6526 has Single Ended Enable Oscillator

Inputs

•

Low Voltage Differential Signaling (LVDS)

Channels Enable Interface for the Fast

Switching Lines

APPLICATIONS

•

Combination DVD/CD Recordable and

Rewritable Drives

•

Low Output Current Noise: 0.24 nA/√Hz

Dual Output: Selectable by SELA/B Pin (Active

HIGH)

•

DVD Camcorders

DVD Recorders

–

SELA = LMH6526 SEB = LMH6525

•

Four Independent Current Channels

DESCRIPTION

–

Gain of 300, 300 mA Write Channel

The LMH™6525/6526 is a laser diode driver for use

in combination DVD/CD recordable and rewritable

systems. The part contains two high-current outputs

for reading and writing the DVD (650 nm) and CD

(780 nm) lasers. Functionality includes read, write

and erase through four separate switched current

channels. The channel currents are summed together

at the selected output to generate multilevel

waveforms for reading, writing and erasing of optical

discs. The LVDS interface delivers DVD write speeds

of 16x and higher while minimizing noise and

crosstalk. The LMH6525/6526 is optimized for both

speed and power consumption to meet the demands

of next generation systems. The part features a 150

mA read channel plus one 300 mA and two 150 mA

write channels, which can be summed to allow a total

output current of 600 mA or greater. The channel

currents are set through four independent current

inputs.

Gain of 150, 150 mA Low-Noise Read

Channel

–

Two Gain of 150, 150 mA Write Channels

600 mA Minimum Combined Output Current

•

Integrated AC Coupled HFM Oscillator

–

Selectable Frequency and Amplitude

Setting

–

By External Resistors

200 MHz to 600 MHz Frequency Range

Amplitude to 100 mA Peak-to-Peak

Modulation

•

Complete Shutdown by ENABLE Pin

5V Single-Supply Operation

Logic inputs TTL and CMOS compatible

Space Saving Package (OFN)

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.

LMH is a trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

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.

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

Block Diagrams

EN4

EN4B

EN4

EN4B

LMH6526

CHANNEL 4

LMH6525

EN3

CHANNEL 3

CHANNEL 2

CHANNEL 3

CHANNEL 2

EN3B

OUTPUT A

OUTPUT B

IOUTA

IOUTB

IOUTA

IOUTB

EN2

EN2B

EN2

EN2B

OUTPUT B

READ CHANNEL

RF OSCILLATOR

READ CHANNEL

RF OSCILLATOR

ENR

ENOSC

ENOSCB

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

DESCRIPTION (CONTINUED)

An on-board High-Frequency Modulator (HFM) oscillator helps reduce low-frequency noise of the laser and is

enabled by applying LVDS levels on the ENOSC pins for the LMH6525, while the LMH6526 is enabled by

applying an asymmetrical signal on the ENOSC pin. The fully differential oscillator circuit minimizes supply line

noise, easing FCC approval of the overall system. The SELA/B pin (active HIGH) selects the output channel and

oscillator settings. External resistors determine oscillator frequency and amplitude for each setting. The write and

erase channels can be switched on and off through dedicated LVDS interface pins.

(1)(2)

Absolute Maximum Ratings

(3)

ESD Tolerance

Human Body Model

2 KV

200V

(4)

Machine Model

Supply Voltages V⁺– V⁻

5.5V

Differential Input Voltage

±5.5V

(5)

Output Short Circuit to Ground

Input Common Mode Voltage

Storage Temperature Range

Continuous

V⁻to V⁺

−65°C to +150°C

+150°C

(6)

Junction Temperature

(1) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and

specifications.

(2) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for

which the device is intended to be functional, but specific performance is not ensured. For specifications, see the Electrical

Characteristics tables.

(3) For testing purposes, ESD was applied using "Human Body Model”; 1.5 kΩ in series with 100 pF.

(4) Machine Model, 0Ω in series with 200 pF.

(5) Applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated ambient temperature can result in

exceeding the maximum allowed junction temperature of 150°C.

(6) The maximum power dissipation is a function of T_J(MAX), θ_JAand T_A. The maximum allowable power dissipation at any ambient

temperature is P_D= (T_J(MAX)— T_A)/ θ_JA. All numbers apply for packages soldered directly onto a PC board..

Operating Ratings

Supply Voltage (V⁺– V⁻)

4.5V ≤ V_S≤ 5.5V

−40°C ≤ T_A≤ 85°C

QFN Package

(1)

Operating Temperature Range (T_A)

(2) (1)

Package Thermal Resistance

(1) Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very

limited self-heating of the device such that T_J= T_A. Parametric performance is as indicated in the electrical tables under conditions of

internal self-heating where T_J> T_A. See Applications section for information on temperature de-rating of this device.

(2) The maximum power dissipation is a function of T_J(MAX), θ_JAand T_A. The maximum allowable power dissipation at any ambient

temperature is P_D= (T_J(MAX)— T_A)/ θ_JA. All numbers apply for packages soldered directly onto a PC board..

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

Operating Ratings (continued)

(θ_JC

)

3°C/W

42°C/W

(θ_JA) (no heatsink)

(3)

(θ_JA) (no heatsink see

)

30.8°C/W

I_INR/3/4

I_IN2

1.5 mA (Max)

1.0 mA (Max)

1000 Ω (Min)

100-600 MHz

10-100 mA_PP

R_FREQ

R_AMP

F_OSC

A_OSC

(3) This figure is taken from a thermal modeling result. The test board is a 4 layer FR-4 board measuring 101 mm x 101 mm x 1.6 mm with

a 3 x 3 array of thermal vias. The ground plane on the board is 50 mm x 50 mm. Ambient temperature in simulation is 22°C, still air.

Power dissipation is 1W.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

(1)

+5V DC Electrical Characteristics

Unless otherwise specified, all limits specified for T_J= 25°C, R_L= 10Ω. Boldface limits apply at the temperature extremes.

(2)

(3)

(2)

Symbol

LVDS

Parameter

Conditions

Min

Typ

Max

Units

(4)

V_I

Input Voltage Range

|V_GPD| < 50 mV

1.7

2.4

(4)

V_IDTH

V_HYST

R_IN

Input Diff. Threshold

Input Diff. Hysteresis

Input Diff. Impedance

Input Current

|V_GPD| < 50 mV

V_IDTHH– V_IDTHL

–100

100

Ω

115

135

I_IN

Excluding R_INCurrent , V_CM= 1.25V

R_INto Ground

μA

Current Channels

R_IN

Input Resistance all Channels

475

580

2.1

675

Ω

I_OS2

Current Offset Channel 2

Channel R,3,4 Off

I_IN= 0, EN = High

I_OS,R,3,4

Current Offset Channel R,3,4

All Channels Off

I_IN= 0, EN = High

1.2

A_IW

Current Gain

Channel 2

345

135

160

386

159

182

1.7

430

180

200

A/A

A_IR

Current Gain

Channel Read

Channel 3 and 4

A_I,3,4

I_LIN-R,2,3,4

Current Gain

Output Current Linearity

200 μA < I_IN< 1000 μA; R_LOAD= 5Ω

Channels Read, 2,3 and 4

IOUT_W

IOUT_R

Output Current

Channel 2 @ 1 mA input current

285

140

300

162

Channel Read

@ 1 mA input current

IOUT_3,4

Output Current

Channel 3 and 4

@ 1 mA input current

160

600

183

(5)

IOUT_TOTALTotal Output Current

All Channels

V_TLO

TTL Low Voltage

Input (H to L), ENR

ENOSC (LMH6526)

1.29

1.40

0.8

V_TLO

TTL Low Voltage

Input (H to L)

B-Select (LMH6525)

A-Select (LMH6526)

V_ELO

V_THI

Enable Low Voltage

TTL High Voltage

Enable Input (H to L)

1.98

1.27

0.8

Input (L to H), ENR

ENOSC (LMH6526)

V_THI

TTL High Voltage

Input (L to H)

1.51

B-Select (LMH6525)

A-Select (LMH6526)

V_EHI

I_Spd

I_Sr1

Enable High Voltage

Enable Input (L to H)

Enable = Low

2.8

2.13

0.003

81.5

Supply Current, Power Down

0.1

Supply Current, Read Mode,

Oscillator Disabled

ENOSC = Low; ENOSCB = High

I2 = I3 = I4 = I_R= 125 μA

100

I_Sr2

Supply Current, Read Mode,

Oscillator Enabled

ENOSC = High; ENOSCB = Low

I2 = I3 = I4 = I_R= 125 μA

R_FA= 3.5 kΩ

81.5

100

I_Swr

I_S

Supply Current, Write Mode

Supply Current

EN2 = EN3 = EN4 = High;

I2 = I3 = I4 = I_R= 125 μA

180

210

All Channels disable, no input current.

SELA/B = Low

R_AA, R_AB, R_FA, R_FB= ∞

(1) Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very

limited self-heating of the device such that T_J= T_A. Parametric performance is as indicated in the electrical tables under conditions of

internal self-heating where T_J> T_A. See Applications section for information on temperature de-rating of this device.

(2) All limits are specified by testing or statistical analysis.

(3) Typical values represent the most likely parametric norm.

(4) V_GPD= ground potential difference voltage between driver and receiver

(5) Total input current is 4 mA (all 4 channels equal) and output currents are summed together (see typical performance characteristics).

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

+5V AC ELECTRICAL CHARACTERISTICS

Unless otherwise specified, all limits specified for T_J= 25°C, I_OUT= 40 mA DC and 40 mA pulse, R_L= 50Ω. Boldface limits

apply at the temperature extremes.

(1)

(2)

(1)

Symbol

Parameter

Write Rise Time

Conditions

Min

Typ

0.6

Max

Units

t_r

t_f

t_r

t_f

t_r

t_f

I_OUT= 40 mA (Read) + 40 mA

(10% to 90%) R_LOAD= 5Ω

Write Fall Time

I_OUT= 40 mA (Read) + 40 mA

(90% to 10%) R_LOAD= 5Ω

1.6

0.6

1.0

0.6

1.0

Write Rise Time

I_OUT= 100 mA (Read) + 100 mA

(10% to 90%) R_LOAD= 5Ω

Write Fall Time

I_OUT= 100 mA (Read) + 100 mA

(90% to 10%) R_LOAD= 5Ω

Write Rise Time

I_OUT= 150 mA (Read) + 150 mA

(10% to 90%) R_LOAD= 5Ω

Write Fall Time

I_OUT= 150 mA (Read) + 150 mA

(90% to 10%) R_LOAD= 5Ω

IN₀

Output Current Overshoot

Output Current Noise

I_OUT= 40 mA (Read) + 40 mA

(3)

I_OUT= 40 mA; R_LOAD= 50Ω;

0.24

nA/√Hz

f = 50 MHz; ENOSC = Low

t_ON

I_OUTON Prod. Delay

Switched on EN2 and EN2B

Switched on ENR

3.1

3.3

3.5

2.8

t_OFF

t_disr

T_enr

t_dis

I_OUTOFF Prop. Delay

Disable Time, Read Channel

Enable Time, Read Channel

Disable Time (Shutdown)

Enable Time (Shutdown)

Channel Bandwidth, −3 dB

Oscillator Frequency

Switched on ENR

Enable = High to Low

Enable = Low to High

I_OUT= 50 mA, All Channels

t_en

4.5

250

360

µs

BW_C

F_OSC

KHz

MHz

R_F= 3.48 kΩ

290

430

Range 200 MHz to 600 MHz

T_DO

T_EO

T_DO

T_EO

Disable Time Oscillator

Enable Time Oscillator

Disable Time Oscillator

Enable Time Oscillator

LMH6525

LMH6526

(1) All limits are specified by testing or statistical analysis.

(2) Typical values represent the most likely parametric norm.

(3) This is the average between the positive and negative overshoot.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

CONNECTION DIAGRAMS

28-Pin (QFN)

Top View

28-Pin (QFN)

Top View

GNDB

IOUTB

GNDB

IOUTB

I3 10

LMH6525

LMH6526

FB 13

AA 14

EN4

FB 13

EN4

15 16

19 20

20 21

15 16 17 18 19

See Package Number NJD0028A

Table 1. Pin Description

Pin #

Description

Laser driver output channel A

LVDS Oscillator Enable pin

Remarks

Internal Oscillator activated if logical input is high

Internal Oscillator activated if logical input is low

Read Channel active if pin is high

LVDS Oscillator Enable pin B (only LMH6525)

Read Channel Enable pin

Chip Enable pin

Chip Enabled if pin is high

Supply Voltage A

Ground Connection A

Read Channel current setting

Channel 2 current setting

1 mA input current result in 150 mA output current

1 mA input current result in 300 mA output current

1 mA input current result in 150 mA output current

Set by external resistor to ground

10.

11.

12.

13.

14.

15.

16.

Channel 3 current setting

Channel 4 current setting

Oscillator Frequency setting Channel A

Oscillator Frequency setting Channel B

Oscillator Amplitude setting Channel A

Oscillator Amplitude setting Channel B

Set by external resistor to ground

Channel select B (LMH6525)

Channel select A (LMH6526)

Channel selected if pin is high

17.

18.

19.

20.

21.

22.

23.

24.

25.

LVDS input Channel 2B

LVDS input Channel 2

LVDS input Channel 3B

LVDS input Channel 3

LVDS input Channel 4B

LVDS input Channel 4

Channel 2 active if logical input is low

Channel 2 active if logical input is high

Channel 3 active if logical input is low

Channel 3 active if logical input is high

Channel 4 active if logical input is low

Channel 4 active if logical input is high

Supply Voltage

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

Table 1. Pin Description (continued)

Pin #

26.

Description

Remarks

Supply Voltage

27.

Laser driver output channel B

Ground Connection B

28.

Truth Tables

Table 2. IOUT Control

ENABLE

ENR

EN2

EN3

EN4

IOUT

OFF

A_R* I_INR

A_R* I_INR+ A₂* I_IN2

A_R* I_INR+ A₃* I_IN3

A_R* I_INR+ A₄* I_IN4

Table 3. Oscillator Control

ENABLE

ENOSC

ENR

EN2

EN3

EN 4

OSCILLATOR

OFF

NOTE

Note: EN2, EN3, EN4 AND ENOSC are LVDS SIGNALS USING THE LMH6525.

EN2, EN3 and EN4 are LVDS signals using the LMH6526.

Waveforms

ENABLE

ENR

EN2B

EN2

EN3B

EN3

EN4B

EN4

AMPLITUDE

SET BY I2

AMPLITUDE

SET BY I3

AMPLITUDE

SET BY I4

SET BY I

IOUTA

SUMMATION OF

I2, I3 and I4

Figure 1. Functional Timing Diagram

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

ENABLE

ENR

IOUTA

dis

Figure 2. Enable Timing

ENABLE

ENR

IOUTA

disr

enr

Figure 3. Read Timing

ENABLE

EN2B,3B,4B

EN2,3,4

OFF

IOUTA

Figure 4. Write Timing

ENABLE

ENR

ENOSC

IOUTA

Figure 5. Oscillator Timing

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

Detailed Block Diagram

EN4

CLOSED IF HIGH

100W

EN4B

500W

100W

EN3

CLOSED IF HIGH

EN3B

500W

100W

EN2

CLOSED IF HIGH

EN2B

IOUTA

IOUTB

500W

CLOSED IF HIGH

ENR

500W

CLOSED IF HIGH

ENOSC

ENOSCB

NC at LMH6526

OSC

CONTROL

SHUTDOWN

CONTROL

SELB (LMH6525)

SELA (LMH6526)

ENABLE

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

Application Schematic

DIGITAL SYSTEM DACs

DAC

BETWEEN

PINS 6

BETWEEN

PINS 26

AND 28

AND 7

DAC

100 nF

47 mF

68 nF

47 mF

DAC

3k 3k

LMH6525

LMH6526

DIGITAL DRIVER

DIGITAL SYSTEM

LOGIC

ENR

IOUTA

EN2

EN2B

LASER

DIODE

EN2B

EN3

EN3B

IOUTB

EN4

EN4B

LASER

DIODE

LVDS

DRIVERS

OSCILLATOR

DIGITAL LOGIC

ENOSC

ENOSCB

SELB

ENOSC

NA for LMH6526

ENOSCB

SELB

SELA for LMH6526

ENABLE

GNDA AND V A ARE ANALOG

SIGNAL GROUND AND POWER.

THEY ARE NOT CONNECTED TO

GNDB AND V

INSIDE THE CHIP

FREQUENCY

AMPLITUDE

LOWER RESISTANCE = HIGHER FREQUENCY AND AMPLITUDE

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

Typical Performance Characteristics

(T_J= 25°C, V⁺= ±5V, V⁻= 0V; Unless Specified).

Oscillator Amplitude

vs.

R_A

vs.

R_A

140

120

100

= 5V

= 150 mA

120

100

= 10W

LOAD

f = 300 MHz

= 5V

= 150 mA

= 10W

LOAD

= 5V

= 5W

f = 300 MHz

LOAD

f = 300 MHz

= 150 mA

= 5W

LOAD

f = 300 MHz

10 20 30 40 50 60 70 80

(kW)

RA (kW)

Figure 6.

Figure 7.

Oscillator Frequency

vs.

R_F

Pulse Response

600

0.5

0.4

0.3

= 5V

= 5W

LOAD

500

400

300

200

100

0.2

0.1

= 5V

= 5W

LOAD

STEP

= 40 mA

10 20 30 40 50 60 70 80

TIME (ns)

(kW)

Figure 8.

Figure 9.

Noise

vs.

Frequency

Headroom & Output Current

vs.

Total Input Current

3.5

900

800

700

2.7

= 5.5V

= 25W

LOAD

2.4

2.1

OSC = OFF

= 40 mA

600

500

1.8

1.5

HEADROOM

2.5

= 5.0V

400

300

1.2

0.9

1.5

= 4.5V

200

100

0.6

0.3

OUTPUT CURRENT

0.5

= 5W

20 30 4050

FREQUENCY (MHz)

TOTAL INPUT CURRENT (mA)

Figure 10.

Figure 11.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

APPLICATION INFORMATION

CIRCUIT DESCRIPTION

General & Spec

The LMH6525/6526 is a 4-channel-input, dual-output laser driver. The dual outputs are meant to drive two

different laser diodes, one for CD reading and writing and one for DVD reading and writing. The part has an

oscillator that can be set for both amplitude and frequency. The oscillator has four input pins for setting both the

amplitude and frequency by connecting external resistors to ground. The part operates at 5V and is capable to

deliver a minimum total output current of 500 mA.

INPUTS

Current-Setting Inputs

The 4 input channels are transconductance-type inputs. This means the output current of the channel is

proportional to the current (not voltage) sourced into the input pin. That is why these pins are designated by the

letter “I” to indicate the current input nature of the pin. The read channel current-setting pin is “I_R”, the Channel 2

current-setting pin is “I2” and so on. Using a transconductance-type input eliminates the high-impedance inputs

associated with a voltage input amplifier. The lower input impedances of the input nodes lowers the susceptibility

of the part to EMI/RFI. The Read Channel (I_R) and Channel 3 (I3) and 4 (I4) current-setting inputs have a gain of

150. The Channel 2 input (I2) has a current gain of 300. Sourcing one milliampere into the pins I_R, I3 or I4, will

result in 150 mA at the output for each Channel, while 1 mA into I2 will result in 300 mA at the output for Channel

2. These currents of 150 mA and 300 mA are the maximum allowable currents per channel. The total allowable

output current from all the channels operating together exceeds 500 mA.

Channel Enable Inputs

Each of the four channels has one (read) or two enable inputs that allow the channel to be turned on or off. The

read channel enable (ENR) is a single-ended TTL/CMOS compatible input. A single-ended signal is adequate for

this channel because the read channel is generally enabled the entire time the drive is reading or writing. The

three write/erase channels need to be operated much faster so these channel enables are LVDS (Low Voltage

Differential Signal) inputs. Each channel has two inputs, such as EN2 and EN2B. Following the standard an

LVDS output consists of a current source of 3.5 mA, and this current produces across the internal termination

resistor of 100Ω in the LMH6525 or LMH6526 a voltage of 350 mV. The polarity of the current through the

resistor can change very quickly thus switching the channel current on or off. The bias level of the LVDS signal is

about 1.2V, so the operating levels are 175 mV above and below this bias level. The ENxB inputs act as the not

input so if the other input is at logical ‘1’ state and the not input at ‘0’ state the channel is activated. The internal

100Ω resister provides a proper termination for the LVDS signals, saving space and simplifying layout and

assembly.

Control Inputs

There are two other control inputs (next to the oscillator enable which is covered in the next section). There are

the global chip Enable and output select pin SELA or SELB. Setting the Enable pin to a level above 2V will

enable the part. This means the supply current raises from sleep mode value to the normal operating values. The

SELA or SELB input (TTL/ CMOS levels) controls which output is active. When at logical ‘1’ state the output

indicated by it’s name is active. The mode of this pin also controls the oscillator circuitry which means that the

appropriate setting resistors become active as described in the next section.

Oscillator Inputs

The oscillator section can be switched on or off by a LVDS signal for the LMH6525 and by a TTL/ CMOS signal

for the LMH6526. When switched on the oscillator will modulate the output current. The settings of the frequency

and amplitude are done by 4 resistors, two for every channel. R_FAand R_FBpins set the oscillator frequency for

the A and B outputs respectively. The R_AAand R_ABpins set the oscillator amplitude for the A and B channels

respectively. These 4 inputs work by having current drawn out of the pin by a setting resistor or potentiometer.

The frequency and amplitude increase by decreasing setting resistor value. There are two charts in the Typical

Performance Characteristics section that relates the setting resistor value to the resulting frequency or amplitude.

Normally the settings for the frequency and amplitude are done by connecting the pin via a resistor to ground. If

needed to program this settings it is possible to connect these R_Fxand R_Axpins via a current limiting resistor to

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

the output of an op amp or DAC. When using such a circuitry the output can be held at a negative voltage, which

means even if the channel pins R_Fxand R_Axare not selected, current is drawn from the pin. This is only true

when the negative voltage has such a value that the internal transistors connected to the pin will conduct. This

will influence the settings of the active pins R_Fxand R_Ax. Due to this effect it is recommended, when using a

negative voltage lower as -0.5V, to disable this voltage simultaneously with the channel.

OUTPUT

The outputs can source currents in excess of 600 mA. The output pins have been designed to have minimal

series inductance in order to minimize current overshoot on fast pulses. The outputs have a saturation voltage of

about 1V. The table below shows the typical output saturation Voltages into a 5Ω load at various supply voltages.

Table 4. Output Saturation

Supply Voltage (V)

Maximum Output (mA) 5Ω

Saturation Voltage (V)

4.5V

5.0V

5.5V

700

777

846

0.8

0.89

1.02

As can be seen, even with a 4.5V supply voltage the part can deliver 700 mA while the saturation voltage is at

0.8V. This means the output voltage of the part can be at maximum 700e-3*5 = 3.5V. With a saturated output

voltage (see Figure 12) of 0.8V the voltage on the supply pin of the part is 4.3V. The used supply voltage is 4.5V

so there is a supply voltage loss of 0.2V over the supply line resistance, but nevertheless the part can drive laser

diodes with a forward voltage up to 3.5V with currents over 500 mA. When operating at 5.5V the part can deliver

currents over 800 mA. In this case the output at the anode of the laser diode is 846e-3*5 = 4.23V, combined with

the saturated output voltage of 1.02V the supply voltage of the part at the power pin is 5.25V and this means the

supply line loss is 0.25V. So at 5.5V supply voltage the part can drive laser diodes with a forward voltage in

access of 4V.

SUPPLY

SUPPLY LINE

RESISTANCE

SATURATED

OUTPUT

VOLTAGE

OUTPUT STAGE

LMH65xx

LASER

DIODE

Figure 12. Output Configuration

Application Hints

SUPPLY SEQUENCING

As the LMH6525/6526 is fabricated in the CMOS7 process, latch-up concerns are minimal. Be aware that

applying a low impedance input to the part when it has no supply voltage will forward bias the ESD diode on the

input pin and then source power into the part’s V_DDpin. If the potential exists for sustained operation with active

inputs and no supply voltage, all the active inputs should have series resistors to limit the current into the input

pins to levels below a few milliamperes.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

DECOUPLING

The LMH6525/6526 has very high output currents changing within a nanosecond. This makes decoupling

especially important. High performance, low impedance ceramic capacitors should be located as close as

possible to the supply pins. The LMH6525/6526 needs two decoupling capacitors, one for the analog power and

ground V_DDA, GNDA) and one for the power side supply and ground (3xV_DDand GNDB). The high level of output

current dictates the power side decoupling capacitor should be 0.1 microfarads minimum. Larger values may

improve rise times depending on the layout and trace impedances of the connections. The capacitors should

have direct connection across the supply pins on the top layer, preferably with small copper-pour planes. These

planes can connect to the bottom side ground and/or power planes with vias but there should be a topside low

impedance path with no vias if possible. (see also Figure 15 Decoupling Capacitors).

OVERSHOOT

As the LMH6525/6526 has fast rise times of less then a nanosecond, any inductance in the output path will

cause overshoot. This includes the inductance in the laser diode itself as well as any trace inductance. A series

connection of a resistor and a capacitor across the laser diode could be helpful to reduce unwanted overshoot or

to reduce the very high peaks caused by the relaxation oscillations of a laser diode when driven from below the

knee voltage. But keep always in mind that this causes a slower rise and/ or fall time. Typical values are 10Ω

and 100 pF. The actual values required depend on the laser diode used and the circuit layout and should be

determined empirically.

THERMAL

General

The LMH6525/6526 is a very high current output device. This means that the device must have adequate heat-

sinking to prevent the die from reaching its absolute maximum rating of 150°C. The primary way heat is removed

from the LMH6525/6526 is through the Die Attach Pad, the large center pad on the bottomside of the device.

Heat is also carried out of the die through the bond wires to the traces. The outputs and the V_DDpads of the

device have double bond wires on this device so they will conduct about twice as much heat to the pad. In any

event, the heat able to be transferred out the bond wires is far less than that which can be conducted out of the

die attach pad. Heat can also be removed from the top of the part but the plastic encapsulation has worse

thermal conductivity then copper. This means a heat sink on top of the part is less effective than the same

copper area on the circuit board that is thermally attached to the Die Attach Pad.

PBC Heatsinks

In order to remove the heat from the die attach pad there must be a good thermal path to large copper pours on

the circuit board. If the part is mounted on a dual-layer board the simplest method is to use 6 or 8 vias under the

die attach pad to connect the pad thermally (as well as electrically, of course) to the bottomside of the circuit

board. The vias can then conduct heat to a copper pour area with a size as large as possible. Please see

application note AN-1187 (Literature Number SNOA401) for guidelines about these vias and QFN packaging in

general.

Derating

It is essential to keep the LMH6525/6526 die under 150°C. This means that if there is inadequate heat sinking

the part may overheat at maximum load while at maximum operating ambient of 85°C. How much power

(current) the part can deliver to the load at elevated ambient temperatures is purely dependent on the amount of

heat sinking the part is provided with.

LAYOUT

Inputs

Critical inputs are the LVDS lines. These are two coupled lines of a certain impedance, mostly 100Ω. For some

reason those lines could have another value but in that case the termination resistance must have the same

value. The differential input resistance of the LMH6525 and LMH6526 is 100Ω and normally the impedance of

the incoming transmission line matches that value. When using a flexible flat cable it is important to know the

impedance of two parallel wires in that cable. Flex cables can have different pitch distances, but a commonly

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

used cable has a pitch of 0.5 mm. When verified by TDR equipment, the measurements show an impedance of

about 142Ω. It is possible to calculate the impedance of such a cable when some parameters are known.

Needed parameters are the pitch (a) of the wires, the thickness (d) en r (see Figure 13). When Checked under a

microscope: the thickness of the wires is 0.3 mm. The pitch is 0.5 mm, while the ;r must be 1 for air. The

impedance of two parallel wires is given by this formula,

Z = (276/r) * log{(2*a)/d}

(1)

With the data above filled in this formula the result is:

Z = 144Ω

(2)

Figure 13. Parallel Wires

Both the measured and the calculated numbers match very closely. The impedance of the flex cable is a physical

parameter so when designing a transmission path using this flex cable, the impedance of the total path must be

based on 140Ω. There is another parameter which is the termination resistance inside the LMH6525 or LMH6526

which is 100Ω. When terminating the 140Ω transmission path with an impedance of 100Ω a mismatch will occur

causing reflections on the transmission line. To solve this problem it is possible to connect directly at the input

terminals of the part two resistors of 20Ω one on every pin to keep it symmetrical. Normally this causes signal

loss over the total extra series resistance of 40Ω when using a voltage source for driving the transmission line.

An advantage of a LVDS source is it’s current nature. The current of a LVDS output is 3.5 mA and this current

produces across a resistor of 140Ω a voltage of 490 mV, while this voltage across the 100Ω internal termination

resistor of the part remains at 350 mV, which is conform the LVDS standard. With the usage of a series

resistance of 40Ω and the termination resistor of 100Ω the total termination resistance now matches the line

impedance and reflections will be as low as possible. A helpful tool for calculating impedances of transmission

lines is the: ‘Transmission Line Rapidesigner’ available from the Texas Instruments Interface Products Group.

Application Note AN-905 (Literature Number SNLA035) details the use of this handy software tool.

The Read Enable and Enable inputs are slower and much less critical. The Oscillator Enable input is toggled in

combination with the write pulse so special attention should be given to this signal to insure it is routed cleanly. It

may be desirable to put a termination resistor close to the LMH6526 for the Enable Oscillator line, to achieve the

best turn-on and turn-off performance of the oscillator.

OUTPUTS

In order to achieve the fastest output rise times the layout of the output lines should be short and tight (see

Figure 14). It is intended that the Output B trace be routed under the decoupling capacitor and that the ground

return for the laser be closely coupled to the output and terminated at the ground side of the decoupling

capacitor.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

Figure 14. Laser Connection

The capacitance on the output lines should also be reduced as much as possible. As always the loop area of the

laser current should be minimized and keep in mind that it is important not to have vias in the current path of the

output lines. Via’s will introduce some inductance which lead to extra overshoot on the pulse shape.

DECOUPLING CAPACITORS

As mentioned before, the decoupling capacitors are critical to the performance of the part. The output section

above mentioned that the power-side decoupling capacitor should be as close as possible to the V_DDand GND

pins and that the B output should pass under the decoupling capacitor. Similarly the analog-side decoupling

capacitor should be as close as possible to the V_DDA and GNDA pins. Figure 15 shows a layout where the

analog (V_DDA and GNDA) decoupling cap C1 is placed next to pins 6 and 7. (Note the layout is rotated 90

degrees from the last figure.) The ground extends into a plane that should connect to the oscillator amplitude and

current setting resistors. C2 is the power-side decoupling capacitor and it can be seen placed as close to the V_DD

and GNDB pins as possible while straddling the B output trace. This layout has also provided for a second power

decoupling capacitor C3 that connects from V_DDto a different GND copper pour. It must be noted that the two

ground planes extending from C2 and C3 must be tied together. This will be shown in the thermal section below.

Bear in mind that the closeness of the parts to the LMH6525/6526 may be dictated by manufacturing rework

considerations such that the LMH6525/6526 can be de-soldered with a hot-air rework station without the need to

remove the capacitors. The relevant manufacturing organization can provide guidelines for this minimum

spacing.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

Figure 15. Decoupling Capacitors

OSCILLATOR RESISTORS

The resistors and/or potentiometers used to set oscillator frequency or amplitude should be as close to the part

as possible. If the grounds are split when using a single-sided flex circuit, it is essential that these resistors and

potentiometers share the same ground as the GNDA pin and decoupling capacitor.

THERMAL

As mentioned previously, the primary way to get heat out of the QFN package is by the large Die Attach Pad at

the center of the part’s underside. On two-layer circuits this can be done with vias. On single-sided circuits the

pad should connect with a copper pour to either the GND pin or, if a better thermal path can be achieved, with

the V_DDpins. Be aware that the unused pins on the part can also be used to connect a copper pour area to the

Die Attach Pad. Figure 16 Heat Sinking (with the same orientation as the first layout example) shows using the

unused pin to provide a thermal path to copper pour heat sinks. In this layout the analog ground has been

separated from the power ground so pin 7 is not connected to the Die Attach Paddle even though it would help

remove heat from the part. The above layout is based on a single-sided circuit board. If a dual-sided circuit board

was used there would also be vias on the Die Attach Pad that would conduct heat to a copper plane on the

bottom side of the board.

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

www.ti.com

Figure 16. Heat Sinking

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

LMH6525, LMH6526

www.ti.com

SNOSAF1B –JUNE 2005–REVISED MARCH 2013

REVISION HISTORY

Changes from Revision A (March 2013) to Revision B

Page

•

Changed layout of National Data Sheet to TI format .......................................................................................................... 18

Submit Documentation Feedback

Product Folder Links: LMH6525 LMH6526

PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead finish/

Ball material

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

(1)

(2)

(3)

(4/5)

(6)

LMH6525SP/NOPB

LMH6526SP/NOPB

ACTIVE

UQFN

NJD

1000 RoHS & Green

Level-1-260C-UNLIM

-40 to 85

L6525SP

L6526SP

⁽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 <=1000ppm threshold. Antimony trioxide based

flame retardants must also meet the <=1000ppm threshold requirement.

⁽³⁾MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

⁽⁴⁾There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

⁽⁵⁾Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

(6)

Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two

lines if the finish value exceeds the maximum column width.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

Addendum-Page 2

PACKAGE MATERIALS INFORMATION

www.ti.com

9-Aug-2022

TAPE AND REEL INFORMATION

REEL DIMENSIONS

TAPE DIMENSIONS

Reel

Diameter

Cavity

A0 Dimension designed to accommodate the component width

B0 Dimension designed to accommodate the component length

K0 Dimension designed to accommodate the component thickness

Overall width of the carrier tape

P1 Pitch between successive cavity centers

Reel Width (W1)

QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE

Sprocket Holes

Q1 Q2

Q3 Q4

Q1 Q2

Q3 Q4

User Direction of Feed

Pocket Quadrants

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

LMH6525SP/NOPB

LMH6526SP/NOPB

UQFN

NJD

1000

178.0

12.4

5.3

1.3

8.0

12.0

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

9-Aug-2022

TAPE AND REEL BOX DIMENSIONS

Width (mm)

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

LMH6525SP/NOPB

LMH6526SP/NOPB

UQFN

NJD

1000

208.0

191.0

35.0

Pack Materials-Page 2

MECHANICAL DATA

NJD0028A

SPA28A (Rev A)

www.ti.com

IMPORTANT NOTICE AND DISCLAIMER

TI PROVIDES TECHNICAL AND RELIABILITY DATA (INCLUDING DATA SHEETS), DESIGN RESOURCES (INCLUDING REFERENCE

DESIGNS), APPLICATION OR OTHER DESIGN ADVICE, WEB TOOLS, SAFETY INFORMATION, AND OTHER RESOURCES “AS IS”

AND WITH ALL FAULTS, AND DISCLAIMS ALL WARRANTIES, EXPRESS AND IMPLIED, INCLUDING WITHOUT LIMITATION ANY

IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD

PARTY INTELLECTUAL PROPERTY RIGHTS.

These resources are intended for skilled developers designing with TI products. You are solely responsible for (1) selecting the appropriate

TI products for your application, (2) designing, validating and testing your application, and (3) ensuring your application meets applicable

standards, and any other safety, security, regulatory or other requirements.

These resources are subject to change without notice. TI grants you permission to use these resources only for development of an

application that uses the TI products described in the resource. Other reproduction and display of these resources is prohibited. No license

is granted to any other TI intellectual property right or to any third party intellectual property right. TI disclaims responsibility for, and you

will fully indemnify TI and its representatives against, any claims, damages, costs, losses, and liabilities arising out of your use of these

resources.

TI’s products are provided subject to TI’s Terms of Sale or other applicable terms available either on ti.com or provided in conjunction with

such TI products. TI’s provision of these resources does not expand or otherwise alter TI’s applicable warranties or warranty disclaimers for

TI products.

TI objects to and rejects any additional or different terms you may have proposed. IMPORTANT NOTICE

Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265

LMH6525 [TI]

相关型号：

SI9130DB

SI9135LG-T1

SI9135LG-T1-E3

SI9135_11

SI9136_11

SI9130CG-T1-E3

SI9130LG-T1-E3

SI9130_11

SI9137

SI9137DB

SI9137LG

SI9122E