LM13700_16 [TI]

Dual Operational Transconductance Amplifiers;


型号：	LM13700_16
厂家：	TEXAS INSTRUMENTS
描述：	Dual Operational Transconductance Amplifiers
文件：	总32页 (文件大小：2031K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LM13700

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LM13700 Dual Operational Transconductance Amplifiers with Linearizing Diodes and

Buffers

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FEATURES

DESCRIPTION

The LM13700 series consists of two current

controlled transconductance amplifiers, each with

differential inputs and a push-pull output. The two

amplifiers share common supplies but otherwise

operate independently. Linearizing diodes are

provided at the inputs to reduce distortion and allow

higher input levels. The result is a 10 dB signal-to-

noise improvement referenced to 0.5 percent THD.

High impedance buffers are provided which are

especially designed to complement the dynamic

range of the amplifiers. The output buffers of the

LM13700 differ from those of the LM13600 in that

their input bias currents (and hence their output DC

levels) are independent of I_ABC. This may result in

performance superior to that of the LM13600 in audio

applications.

•

g_mAdjustable over 6 Decades

Excellent g_mLinearity

•

Excellent Matching between Amplifiers

Linearizing Diodes

High Impedance Buffers

High Output Signal-to-Noise Ratio

APPLICATIONS

•

Current-Controlled Amplifiers

Current-Controlled Impedances

Current-Controlled Filters

Current-Controlled Oscillators

Multiplexers

Timers

Sample-and-Hold circuits

Connection Diagram

Figure 1. PDIP and SOIC Packages-Top View

See Package Number D0016A or NFG0016E

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.

All 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.

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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.

(1)

Absolute Maximum Ratings

Supply Voltage

LM13700

36 V_DCor ±18V

Power Dissipation ⁽²⁾T_A= 25°C

LM13700N

570 mW

±5V

Differential Input Voltage

Diode Bias Current (I_D)

2 mA

Amplifier Bias Current (I_ABC

)

2 mA

Output Short Circuit Duration

Continuous

20 mA

(3)

Buffer Output Current

Operating Temperature Range

LM13700N

0°C to +70°C

+V_Sto −V_S

DC Input Voltage

Storage Temperature Range

Soldering Information

PDIP Package

−65°C to +150°C

Soldering (10 sec.)

SOIC Package

260°C

Vapor Phase (60 sec.)

Infrared (15 sec.)

215°C

220°C

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

which the device is functional, but do not ensure specific performance limits.

(2) For operation at ambient temperatures above 25°C, the device must be derated based on a 150°C maximum junction temperature and a

thermal resistance, junction to ambient, as follows: LM13700N, 90°C/W; LM13700M, 110°C/W.

(3) Buffer output current should be limited so as to not exceed package dissipation.

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(1)

Electrical Characteristics

Parameter

LM13700

Units

Test Conditions

Min

Typ

0.4

0.3

0.5

0.1

0.4

Max

Input Offset Voltage (V_OS

)

Over Specified Temperature Range

I_ABC= 5 μA

V_OSIncluding Diodes

Input Offset Change

Input Offset Current

Input Bias Current

Diode Bias Current (I_D) = 500 μA

5 μA ≤ I_ABC≤ 500 μA

μA

0.6

Over Specified Temperature Range

μA

Forward Transconductance (g_m)

6700

5400

9600

13000

μmho

g_mTracking

0.3

Peak Output Current

R_L= 0, I_ABC= 5 μA

μA

R_L= 0, I_ABC= 500 μA

350

300

500

650

R_L= 0, Over Specified Temp Range

Peak Output Voltage

Positive

R_L= ∞, 5 μA ≤ I_ABC≤ 500 μA

I_ABC= 500 μA, Both Channels

+12

+14.2

−14.4

2.6

Negative

−12

Supply Current

V_OSSensitivity

Positive

ΔV_OS/ΔV⁺

ΔV_OS/ΔV⁻

150

μV/V

Negative

CMRR

110

±13.5

Common Mode Range

Crosstalk

±12

(2)

Referred to Input

100

20 Hz < f < 20 kHz

Differential Input Current

Leakage Current

I_ABC= 0, Input = ±4V

0.02

0.2

100

I_ABC= 0 (Refer to Test Circuit)

Input Resistance

kΩ

Open Loop Bandwidth

Slew Rate

MHz

V/μs

μA

Unity Gain Compensated

(2)

Buffer Input Current

Peak Buffer Output Voltage

0.5

(2)

(1) These specifications apply for V_S= ±15V, T_A= 25°C, amplifier bias current (I_ABC) = 500 μA, pins 2 and 15 open unless otherwise

specified. The inputs to the buffers are grounded and outputs are open.

(2) These specifications apply for V_S= ±15V, I_ABC= 500 μA, R_OUT= 5 kΩ connected from the buffer output to −V_Sand the input of the

buffer is connected to the transconductance amplifier output.

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Schematic Diagram

Figure 2. One Operational Transconductance Amplifier

Typical Application

Figure 3. Voltage Controlled Low-Pass Filter

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Typical Performance Characteristics

Input Offset Voltage

Input Offset Current

Figure 4.

Figure 5.

Input Bias Current

Peak Output Current

Figure 6.

Figure 7.

Peak Output Voltage and

Common Mode Range

Leakage Current

Figure 8.

Figure 9.

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Typical Performance Characteristics (continued)

Input Leakage

Transconductance

Figure 10.

Figure 11.

Amplifier Bias Voltage vs.

Amplifier Bias Current

Input Resistance

Figure 12.

Figure 13.

Input and Output Capacitance

Output Resistance

Figure 14.

Figure 15.

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Typical Performance Characteristics (continued)

Distortion

vs.

Differential

Input Voltage

Voltage

vs.

Amplifier

Bias Current

Figure 16.

Figure 17.

Output Noise

vs.

Frequency

Figure 18.

Figure 19. Unity Gain Follower

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Typical Performance Characteristics (continued)

Figure 20. Leakage Current Test Circuit

Figure 21. Differential Input Current Test Circuit

Circuit Description

The differential transistor pair Q₄and Q₅form a transconductance stage in that the ratio of their collector currents

is defined by the differential input voltage according to the transfer function:

(1)

where V_INis the differential input voltage, kT/q is approximately 26 mV at 25°C and I₅and I₄are the collector

currents of transistors Q₅and Q₄respectively. With the exception of Q₁₂and Q₁₃, all transistors and diodes are

identical in size. Transistors Q₁and Q₂with Diode D₁form a current mirror which forces the sum of currents I₄

and I₅to equal I_ABC

I₄+ I₅= I_ABC

(2)

where I_ABCis the amplifier bias current applied to the gain pin.

For small differential input voltages the ratio of I₄and I₅approaches unity and the Taylor series of the In function

can be approximated as:

(3)

(4)

Collector currents I₄and I₅are not very useful by themselves and it is necessary to subtract one current from the

other. The remaining transistors and diodes form three current mirrors that produce an output current equal to I₅

minus I₄thus:

(5)

The term in brackets is then the transconductance of the amplifier and is proportional to I_ABC

Linearizing Diodes

For differential voltages greater than a few millivolts, Equation 3 becomes less valid and the transconductance

becomes increasingly nonlinear. Figure 22 demonstrates how the internal diodes can linearize the transfer

function of the amplifier. For convenience assume the diodes are biased with current sources and the input

signal is in the form of current I_S. Since the sum of I₄and I₅is I_ABCand the difference is I_OUT, currents I₄and I₅

can be written as follows:

(6)

Since the diodes and the input transistors have identical geometries and are subject to similar voltages and

temperatures, the following is true:

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(7)

Notice that in deriving Equation 7 no approximations have been made and there are no temperature-dependent

terms. The limitations are that the signal current not exceed I_D/2 and that the diodes be biased with currents. In

practice, replacing the current sources with resistors will generate insignificant errors.

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APPLICATIONS

Voltage Controlled Amplifiers

Figure 23 shows how the linearizing diodes can be used in a voltage-controlled amplifier. To understand the

input biasing, it is best to consider the 13 kΩ resistor as a current source and use a Thevenin equivalent circuit

as shown in Figure 24. This circuit is similar to Figure 22 and operates the same. The potentiometer in Figure 23

is adjusted to minimize the effects of the control signal at the output.

Figure 22. Linearizing Diodes

For optimum signal-to-noise performance, I_ABCshould be as large as possible as shown by the Output Voltage

vs. Amplifier Bias Current graph. Larger amplitudes of input signal also improve the S/N ratio. The linearizing

diodes help here by allowing larger input signals for the same output distortion as shown by the Distortion vs.

Differential Input Voltage graph. S/N may be optimized by adjusting the magnitude of the input signal via R_IN

(Figure 23) until the output distortion is below some desired level. The output voltage swing can then be set at

any level by selecting R_L.

Although the noise contribution of the linearizing diodes is negligible relative to the contribution of the amplifier's

internal transistors, I_Dshould be as large as possible. This minimizes the dynamic junction resistance of the

diodes (r_e) and maximizes their linearizing action when balanced against R_IN. A value of 1 mA is recommended

for I_Dunless the specific application demands otherwise.

Figure 23. Voltage Controlled Amplifier

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Figure 24. Equivalent VCA Input Circuit

Stereo Volume Control

The circuit of Figure 25 uses the excellent matching of the two LM13700 amplifiers to provide a Stereo Volume

Control with a typical channel-to-channel gain tracking of 0.3 dB. R_Pis provided to minimize the output offset

voltage and may be replaced with two 510Ω resistors in AC-coupled applications. For the component values

given, amplifier gain is derived for Figure 23 as being:

(8)

If V_Cis derived from a second signal source then the circuit becomes an amplitude modulator or two-quadrant

multiplier as shown in Figure 26, where:

(9)

The constant term in the above equation may be cancelled by feeding I_S× I_DR_C/2(V− + 1.4V) into I_O. The circuit

of Figure 27 adds R_Mto provide this current, resulting in a four-quadrant multiplier where R_Cis trimmed such that

V_O= 0V for V_IN2= 0V. R_Malso serves as the load resistor for I_O.

Figure 25. Stereo Volume Control

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Figure 26. Amplitude Modulator

Figure 27. Four-Quadrant Multiplier

Noting that the gain of the LM13700 amplifier of Figure 24 may be controlled by varying the linearizing diode

current I_Das well as by varying I_ABC, Figure 28 shows an AGC Amplifier using this approach. As V_Oreaches a

high enough amplitude (3V_BE) to turn on the Darlington transistors and the linearizing diodes, the increase in I_D

reduces the amplifier gain so as to hold V_Oat that level.

Voltage Controlled Resistors

An Operational Transconductance Amplifier (OTA) may be used to implement a Voltage Controlled Resistor as

shown in Figure 29. A signal voltage applied at R_Xgenerates a V_INto the LM13700 which is then multiplied by

the g_mof the amplifier to produce an output current, thus:

(10)

where g_m≈ 19.2I_ABCat 25°C. Note that the attenuation of V_Oby R and R_Ais necessary to maintain V_INwithin the

linear range of the LM13700 input.

Figure 30 shows a similar VCR where the linearizing diodes are added, essentially improving the noise

performance of the resistor. A floating VCR is shown in Figure 31, where each “end” of the “resistor” may be at

any voltage within the output voltage range of the LM13700.

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Figure 28. AGC Amplifier

Figure 29. Voltage Controlled Resistor, Single-Ended

Figure 30. Voltage Controlled Resistor with Linearizing Diodes

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Voltage Controlled Filters

OTA's are extremely useful for implementing voltage controlled filters, with the LM13700 having the advantage

that the required buffers are included on the I.C. The VC Lo-Pass Filter of Figure 32 performs as a unity-gain

buffer amplifier at frequencies below cut-off, with the cut-off frequency being the point at which X_C/g_mequals the

closed-loop gain of (R/R_A). At frequencies above cut-off the circuit provides a single RC roll-off (6 dB per octave)

of the input signal amplitude with a −3 dB point defined by the given equation, where g_mis again 19.2 × I_ABCat

room temperature. Figure 33 shows a VC High-Pass Filter which operates in much the same manner, providing a

single RC roll-off below the defined cut-off frequency.

Additional amplifiers may be used to implement higher order filters as demonstrated by the two-pole Butterworth

Lo-Pass Filter of Figure 34 and the state variable filter of Figure 35. Due to the excellent g_mtracking of the two

amplifiers, these filters perform well over several decades of frequency.

Figure 31. Floating Voltage Controlled Resistor

Figure 32. Voltage Controlled Low-Pass Filter

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Figure 33. Voltage Controlled Hi-Pass Filter

Figure 34. Voltage Controlled 2-Pole Butterworth Lo-Pass Filter

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Figure 35. Voltage Controlled State Variable Filter

Voltage Controlled Oscillators

The classic Triangular/Square Wave VCO of Figure 36 is one of a variety of Voltage Controlled Oscillators which

may be built utilizing the LM13700. With the component values shown, this oscillator provides signals from 200

kHz to below 2 Hz as I_Cis varied from 1 mA to 10 nA. The output amplitudes are set by I_A× R_A. Note that the

peak differential input voltage must be less than 5V to prevent zenering the inputs.

A few modifications to this circuit produce the ramp/pulse VCO of Figure 37. When V_O2is high, I_Fis added to I_C

to increase amplifier A1's bias current and thus to increase the charging rate of capacitor C. When V_O2is low, I_F

goes to zero and the capacitor discharge current is set by I_C.

The VC Lo-Pass Filter of Figure 32 may be used to produce a high-quality sinusoidal VCO. The circuit of

Figure 37 employs two LM13700 packages, with three of the amplifiers configured as lo-pass filters and the

fourth as a limiter/inverter. The circuit oscillates at the frequency at which the loop phase-shift is 360° or 180° for

the inverter and 60° per filter stage. This VCO operates from 5 Hz to 50 kHz with less than 1% THD.

Figure 36. Triangular/Square-Wave VCO

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Figure 37. Ramp/Pulse VCO

Figure 38. Sinusoidal VCO

Figure 39 shows how to build a VCO using one amplifier when the other amplifier is needed for another function.

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Figure 39. Single Amplifier VCO

Additional Applications

Figure 40 presents an interesting one-shot which draws no power supply current until it is triggered. A positive-

going trigger pulse of at least 2V amplitude turns on the amplifier through R_Band pulls the non-inverting input

high. The amplifier regenerates and latches its output high until capacitor C charges to the voltage level on the

non-inverting input. The output then switches low, turning off the amplifier and discharging the capacitor. The

capacitor discharge rate is speeded up by shorting the diode bias pin to the inverting input so that an additional

discharge current flows through D_Iwhen the amplifier output switches low. A special feature of this timer is that

the other amplifier, when biased from V_O, can perform another function and draw zero stand-by power as well.

Figure 40. Zero Stand-By Power Timer

The operation of the multiplexer of Figure 41 is very straightforward. When A1 is turned on it holds V_Oequal to

V_IN1and when A2 is supplied with bias current then it controls V_O. C_Cand R_Cserve to stabilize the unity-gain

configuration of amplifiers A1 and A2. The maximum clock rate is limited to about 200 kHz by the LM13700 slew

rate into 150 pF when the (V_IN1–V_IN2) differential is at its maximum allowable value of 5V.

The Phase-Locked Loop of Figure 42 uses the four-quadrant multiplier of Figure 27 and the VCO of Figure 39 to

produce a PLL with a ±5% hold-in range and an input sensitivity of about 300 mV.

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Figure 41. Multiplexer

Figure 42. Phase Lock Loop

The Schmitt Trigger of Figure 43 uses the amplifier output current into R to set the hysteresis of the comparator;

thus V_H= 2 × R × I_B. Varying I_Bwill produce a Schmitt Trigger with variable hysteresis.

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Figure 43. Schmitt Trigger

Figure 44 shows a Tachometer or Frequency-to-Voltage converter. Whenever A1 is toggled by a positive-going

input, an amount of charge equal to (V_H–V_L) C_tis sourced into C_fand R_t. This once per cycle charge is then

balanced by the current of V_O/R_t. The maximum F_INis limited by the amount of time required to charge C_tfrom

V_Lto V_Hwith a current of I_B, where V_Land V_Hrepresent the maximum low and maximum high output voltage

swing of the LM13700. D1 is added to provide a discharge path for C_twhen A1 switches low.

The Peak Detector of Figure 45 uses A2 to turn on A1 whenever V_INbecomes more positive than V_O. A1 then

charges storage capacitor C to hold V_Oequal to V_INPK. Pulling the output of A2 low through D1 serves to turn

off A1 so that V_Oremains constant.

Figure 44. Tachometer

Figure 45. Peak Detector and Hold Circuit

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The Ramp-and-Hold of Figure 47 sources I_Binto capacitor C whenever the input to A1 is brought high, giving a

ramp-rate of about 1V/ms for the component values shown.

The true-RMS converter of Figure 48 is essentially an automatic gain control amplifier which adjusts its gain such

that the AC power at the output of amplifier A1 is constant. The output power of amplifier A1 is monitored by

squaring amplifier A2 and the average compared to a reference voltage with amplifier A3. The output of A3

provides bias current to the diodes of A1 to attenuate the input signal. Because the output power of A1 is held

constant, the RMS value is constant and the attenuation is directly proportional to the RMS value of the input

voltage. The attenuation is also proportional to the diode bias current. Amplifier A4 adjusts the ratio of currents

through the diodes to be equal and therefore the voltage at the output of A4 is proportional to the RMS value of

the input voltage. The calibration potentiometer is set such that V_Oreads directly in RMS volts.

Figure 46. Sample-Hold Circuit

Figure 47. Ramp and Hold

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Figure 48. True RMS Converter

The circuit of Figure 49 is a voltage reference of variable Temperature Coefficient. The 100 kΩ potentiometer

adjusts the output voltage which has a positive TC above 1.2V, zero TC at about 1.2V, and negative TC below

1.2V. This is accomplished by balancing the TC of the A2 transfer function against the complementary TC of D1.

The wide dynamic range of the LM13700 allows easy control of the output pulse width in the Pulse Width

Modulator of Figure 50.

For generating I_ABCover a range of 4 to 6 decades of current, the system of Figure 51 provides a logarithmic

current out for a linear voltage in.

Since the closed-loop configuration ensures that the input to A2 is held equal to 0V, the output current of A1 is

equal to I₃= −V_C/R_C.

The differential voltage between Q1 and Q2 is attenuated by the R1,R2 network so that A1 may be assumed to

be operating within its linear range. From Equation 5, the input voltage to A1 is:

(11)

The voltage on the base of Q1 is then

(12)

The ratio of the Q1 and Q2 collector currents is defined by:

(13)

Combining and solving for I_ABCyields:

(14)

This logarithmic current can be used to bias the circuit of Figure 25 to provide temperature independent stereo

attenuation characteristic.

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Figure 49. Delta VBE Reference

Figure 50. Pulse Width Modulator

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Figure 51. Logarithmic Current Source

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REVISION HISTORY

Changes from Revision D (March 2013) to Revision E

Page

•

Changed layout of National Data Sheet to TI format .......................................................................................................... 24

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PACKAGE OPTION ADDENDUM

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PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead/Ball Finish

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

(1)

(2)

(6)

(3)

(4/5)

LM13700M

NRND

ACTIVE

SOIC

TBD

Call TI

CU SN

Call TI

0 to 70

LM13700M

LM13700M/NOPB

Green (RoHS

& no Sb/Br)

Level-1-260C-UNLIM

LM13700M

LM13700MX

NRND

SOIC

2500

TBD

Call TI

CU SN

Call TI

0 to 70

LM13700M

LM13700MX/NOPB

ACTIVE

Green (RoHS

& no Sb/Br)

Level-1-260C-UNLIM

LM13700N

NRND

PDIP

NFG

TBD

Call TI

CU SN

Call TI

0 to 70

LM13700N

LM13700N/NOPB

ACTIVE

Pb-Free

(RoHS)

Level-1-NA-UNLIM

⁽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⁾Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

⁽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.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

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1-Nov-2013

⁽⁶⁾Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish 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 2

PACKAGE MATERIALS INFORMATION

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8-Apr-2013

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

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

(mm) W1 (mm)

LM13700MX

SOIC

2500

330.0

16.4

6.5

10.3

2.3

8.0

16.0

LM13700MX/NOPB

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

8-Apr-2013

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

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

LM13700MX

SOIC

2500

367.0

35.0

LM13700MX/NOPB

Pack Materials-Page 2

MECHANICAL DATA

NFG0016E

N0016E

N16E (Rev G)

www.ti.com

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LM13700_16 [TI]

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