DC1774A-A - LINEAR TECHNOLOGY

dc1774aaf

DEMO MANUAL DC1774A-A

Description

LTC6430-15

100MHZ to 300MHZ Differential

ADC Driver/IF Amplifier

Demonstration circuit 1774A-A is a differential ADC

driver/IF amplifier featuring the LT C

6430-15. It is part

of the DC1774A demo board family supporting the

LTC643X-YY amplifier series. The DC1774A-A is opti-

mized for a frequency range of 100MHz to 300MHz and

utilizes a minimum of passive external components to

configure the amplifier for this application. L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear

Technology Corporation. All other trademarks are the property of their respective owners.

performance summary

Because the LTC6430-15 has 100Ω differential input and

output impedance, the demo circuit uses transformers to

convert the impedance to 50Ω single-ended allowing easy

evaluation with commercially available RF test equipment.

Design files for this circuit board are available at

http://www.linear.com/demo

SYMBOL PARAMETER CONDITIONS VALUE / UNIT

Power Supply

VCC Operating Supply Range All VCC Pins Plus OUT Pins 4.75V to 5.25V

ICC Current Consumption Total Current 160mA

Specifications are at TA = 25°C, VCC = 5V

Frequency

(MHz)

Power Gain

|S21|

(dB)

Output

Third-Order

Intercept Point1

OIP3

(dBm)

Output

Third-Order

Intermodulation1

OIM3

(dBc)

Second

Harmonic

Distortion 2

HD2

(dBc)

Third Harmonic

Distortion 2

HD3

(dBc)

Output 1dB

Compression

Point

P1dB

(dBm)

Noise Figure 3

(dB)

50 13.1 47.1 –90.2 –83.3 –93.1 21.8 5.2

100 14.5 47.3 –90.5 –84.6 –95.3 22.6 4.1

200 14.5 47.2 –90.3 –86.6 –90.9 22.2 4.0

240 14.2 50.0 –96.0 –83.8 (4) –85.2 (4) 22.2 4.1

300 13.6 47.0 –90.0 –73.6 (4) –83.4 (4) 22.0 4.4

400 12.2 46.4 –88.8 –56.1 (4) –85.0 (4) 21.3 5.1

All figures are referenced to J7 (input port) and J8 (output port).

Note 1: Two-tone test condition: Output power level = 2dBm/tone;

tone spacing = 1MHz.

Note 2: Single-tone test condition: Output power level = 8dBm.

Note 3: Small signal noise figure.

Note 4: Performance degraded due to transformers’ being out of working

frequency range.

dc1774aaf

DEMO MANUAL DC1774A-A

Block Diagram

operation

Demo Circuit 1774A-A is a highly linear fixed-gain ampli-

fier. The LTC6430-15 is internally matched to a 100Ω

differential source and load impedance from 20MHz to

1300MHz. Due to the unpopularity of 100Ω differential

test equipment, transformers have been added to convert

impedance from differential 100Ω to single-ended 50Ω

for the input and the output ports. The frequency range

of the circuit is limited by the balun transformers. Hence,

this demo board works best with a frequency range from

100MHz to 300MHz. Figure2 shows the performance of

the demo board.

Figure 1. LTC6430-15 Device Block Diagram

Figure 2. Demo Board DC1774A-A S-Parameters

FREQUENCY (MHz) dc1774aa F02

–28

–24

–20

–16

–12

–8

–4

0 100 200 300 400

|S11,|S12|,|S22| (dB)

|S21| (dB)

NOMINAL WORKING

FREQUENCY RANGE

|S21|

|S22|

|S11|

|S12|

dc1774aa F01

VCC

9, 22

+IN

BIAS AND TEMPERATURE

COMPENSATION

GND

8, 14, 17, 23 AND PADDLE 25

GND

8, 14, 17, 23

AND PADDLE 25

–IN

+OUT

T_DIODE

–OUT

dc1774aaf

DEMO MANUAL DC1774A-A

operation

Figure 3 shows the simplified demo circuit schematic. It

requires a minimum of passive supporting components.

The 2:1 transformers convert the differential to single-

ended 50Ω for compatibility with most test equipment.

The input and output DC-blocking capacitors (C1, C2,

C3 and C4) are required because this device is inter-

nally biased for optimal operation. The frequency appropri-

ate choke (L1 and L2) and the decoupling capacitors (C5,

C21, C22 and C23) provide bias to the RF ±OUT nodes. Only

a single 5V supply is necessary for VCC pins on the device.

An optional input stability network has been added. It

consists of a parallel 62pF (C8 and C9) and 348Ω (R1

and R2) input network to insure low frequency stability.

Figure 3. Simplified Demo Board DC1774A-A Schematic

Table 1 shows the function of each input and output on

the board.

Table 1. DC1774A-A Board I/O Descriptions

CONNECTOR FUNCTION

J7 (+IN) Single-Ended Input.

Impedance-matched to 50Ω. Drive from a

50Ω network analyzer or signal source.

J8 (–OUT) Single-Ended Output.

Impedance-matched to 50Ω. Drive from a

50Ω network analyzer or spectrum analyzer.

E3 or J11 (VCC)Positive Supply Voltage Source.

E6 or J18 (GND) Negative Supply Ground.

+5V

VCC

T4 = ADT2-1T+

560nH

348 C21

1000pF

J11

+5V

0603

C23

0.1uF

1000pF

560nH

+IN

VCC

R19

OPT

62pF

VCC

J18

GND

C20

1000pF

0603

C14

1000pF

-OUT

T3 = ADT2-1T+

10 21

DNC

GND

DNC

+IN

DNC

GND

DNC DNC

DNC

GND

VCC

DNC

+OUT

T_DIODE

DNC

-IN

VCC

DNC

-OUT

DNC

GND

1000pF

U1 = LTC6430-15

C22

0.1uF

1000pF

SMA

GND

348

VCC

62pF

C15

1000pF

SMA

Stability Network

dc1774aaf

DEMO MANUAL DC1774A-A

setup anD testing signal sources

The LTC6430-15 is an amplifier with high linearity per-

formance, therefore output intermodulation products are

very low. For this reason, it drives most test equipment

and test setups to their limits. Consequently, accurate

measurement of the third-order intercept point for a low

distortion IC such as the LTC6430-15 requires certain

precautions to be observed in the test setup and testing

procedure.

SETUP SIGNAL SOURCES

Figure 5 shows a proposed IP3 test setup. This setup has

low phase noise, good reverse isolation, high dynamic

range, sufficient harmonic filtering and wideband imped-

ance matching. The setup is outlined here:

a. High performance signal generators 1 and 2 (HP8644A)

should be used in the setup. These suggested genera-

tors have low harmonic distortion and very low phase

noise.

b. High linearity ampliﬁers to improve isolation. They

prevent the two signal generators from crosstalking

with each other and provide higher output power.

c. A lowpass ﬁlter to suppress harmonic contents from

interfering with the test signal.

d. The signal combiner (from Mini-Circuits, ADP-2-9)

combines the two isolated input signals. This combiner

has a typical isolation of 27dB. For better VSWR and

isolation, use the H-9 signal combiner from M/A-COM,

which features >40dB isolation and a wider frequency

range. Passive devices (e.g., combiners) with magnetic

elements can contribute nonlinearity to the signal chain

and should be used cautiously.

e. The attenuator pads, on all three ports of the signal

combiner, will support further isolation of the two input

signal sources. They will reduce reﬂection and promote

maximum power transfer with wideband impedance

matching.

Additional Information

The particular element values shown in the demo board

schematic are chosen for wide bandwidth operation.

Depending on the desired frequency, performance may

be improved by the proper selection of these supporting

components.

As with any RF device, minimizing ground inductance

is critical. Care should be taken with the board layout

because of these exposed pad packages. The maximum

number of minimum diameter vias holes should be placed

underneath the exposed pad. This will ensure good RF

ground and low thermal impedance. Maximizing the

copper ground plane will also improve heat spreading

and low inductance. It is a good idea to cover the via

holes with solder mask on the back side of the PCB to

prevent solder from wicking away from the critical PCB

to the exposed pad interface.

The DC1774A-A has a nominal working frequency range

from 100MHz to 300MHz. It is not intended for operation

down to DC. The lower frequency cutoff is limited by on-

chip matching elements.

Figure 6 shows the generic PCB schematic for the

LTC643X-YY amplifier series. The board can be modi-

fied for multiple demo board versions. For example,

both DC1774A-A and DC1774A-B demo boards have a

differential amplifier at U1, therefore, the board is using

transformers to transform from differential to single-

ended input and output. Likewise, the DC1774A-C is a

single-ended demo board; it uses the LTC6431-15 for

single-ended input and output.

operation

dc1774aaf

DEMO MANUAL DC1774A-A

setup anD testing signal sources

TESTING SIGNAL SOURCES

The testing signal should be evaluated and optimized before

it is used for measurements. The following outlines the

necessary steps to achieve optimization:

a. Apply two independent signals, f1 and f2, from signal

generator 1 and signal generator 2 at 240MHz and

241MHz while setting amplitude = –12dBm per tone

at the combined output.

b. Connect the combined signal directly to the spectrum

analyzer (without the DUT).

c. Adjust the spectrum analyzer for the maximum possible

resolution of the intermodulation products amplitude

in dBc relative to the main tone power. A narrower

resolution bandwidth will take a longer time to sweep.

Optimize the dynamic range of the spectrum analyzer

by adjusting input attenuation.

First increase the spectrum analyzer input attenuation

(normally in steps of 5dB or 10dB). If the IMD product

levels decrease when the input attenuation is increased,

then the input power level was too high for the spectrum

analyzer to make a valid measurement. In other words,

the spectrum analyzer 1st mixer was overloaded and

producing its own IMD products. If the IMD reading

holds constant with increased input attenuation, then

a sufﬁcient amount of attenuation was present. Adding

too much attenuation will raise the noise ﬂoor and bury

the intended IMD signal. Therefore, select just enough

attenuation to achieve a stable and valid measurement.

d. In order to achieve a valid measurement result, the

test system must have lower distortion than the DUT

intermodulation. For example, to measure a 47dBm

OIP3, the measured intermodulation products will be

–90dBc below the –12dBm per tone input level and

the test system must have intermodulation products

approximately –96dBc or better. For best results, the

IMD or noise ﬂoor should be at least –100dBc before

connecting the DUT.

Testing the DUT

At this point, the input level has been established at

–12dBm per tone, and the input IMD from the test setup

is well suppressed at –96dBm max. Furthermore, the

spectrum analyzer is set up to measure very low level

IMD components.

a. Insert the DUT and output attenuator into the setup,

inline between the signal source and the spectrum

analyzer. The output attenuator should match the DUT

gain.

b. Fine tune the signal generator levels by a small amount

if necessary (<1dB), to keep output power at 2dBm per

tone at the ampliﬁer output.

c. Measure the output IMD level using the same optimized

setup as previous. Based on the output power level of

2dBm per tone, and knowing the IMD level, OIP3 can

be calculated.

dc1774aaf

DEMO MANUAL DC1774A-A

Quick start proceDure

Demo Circuit 1774A-A can be set up to evaluate the per-

formance of the LTC6430-15. Refer to Figures 4 and 5 for

proper equipment connections and follow this procedure:

Single-Tone Measurement:

1. The power labels of +5V and GND directly correspond

to the power supply. Typical current consumption of

the LTC6430-15 is about 160mA.

2. Apply an input signal to J7. A low distortion, low noise

signal source with an external high order lowpass ﬁlter

will yield the best performance. The input signal is

–10dBm. The input is impedance-matched to 50Ω .

3. Observe the output via J8. The measured power at

the analyzer should be about 4dBm. The output is

impedance-matched to 50Ω, suitable for the input of

a network or spectrum analyzer.

Two-Tone Measurement:

Connect all test equipment as suggested in Figure 8.

1. The power labels of +5V and GND directly correspond

to the power supply. Typical current consumption of

the LTC6430-15 is about 160mA.

2. Apply two independent signals, f1 and f2, from SG1

and SG2, at 240MHz and 241MHz, respectively.

Figure 4. Proper Equipment Setup for Gain and Single-Tone Measurement

(HP8644A)

LOWPASS

FILTER

(OPTIONAL)

3dB

ATTENUATION

PAD

(OPTIONAL)

SIGNAL

GENERATOR

SPECTRUM

ANALYZER

COAXIAL

CABLE

ROHDE AND

SCHWARZ

FSEM30

dc1774aa F04

VCC = 4.75V TO 5.25V

DC POWER SUPPLY

GND V+

ASSY U1

FREQUENCY

(MHz)

–A LTC6430AIUF-15 100 TO 300

–B LTC6430AIUF-15 400 TO 1000

–C LTC6431AIUF-15 100 TO 1200

dc1774aaf

DEMO MANUAL DC1774A-A

Quick start proceDure

Figure 5. Proper Equipment Setup for IP3 Measurement

3. Monitor the output tone level on the spectrum analyz-

er. Adjust signal generator levels such that the output

power measures 2dBm/tone at the ampliﬁer output,

J8, after correcting for external cable losses and at-

tenuations.

4. Change the spectrum analyzer’s center frequency and

observe the two IM3 tones at 1MHz below and above

the input frequencies. The frequencies of IM3_LOW and

IM3_HIGH are 239MHz and 242MHz, respectively.

For this setup, the Rohde and Schwarz FSEM30 spec-

trum analyzer was used. This spectrum analyzer has

a typical 20dBm third-order intercept point (TOI). The

Rohde and Schwarz FSU can also be used. The system,

as described, can measure OIP3 up to 50dBm.

(HP8644A)

APPROX.

–12dBm/TONE

2dBm/TONE

COMBINER

MINI-CIRCUITS

ADP-2-9

AMPLIFIER

MINI-CIRCUITS, ZHL-2,

OR EQUIVALENT

AMPLIFIER

MINI-CIRCUITS, ZHL-2,

OR EQUIVALENT

LOWPASS FILTER

6dB ATTENUATION PAD

(OPTIONAL)

6dB ATTENUATION PAD

(OPTIONAL)

3dB

ATTENUATION

PAD

SIGNAL

GENERATOR 2

SIGNAL

GENERATOR 1

SPECTRUM

ANALYZER

14dB

ATTENUATION PAD

(MATCHES DUT GAIN)

COAXIAL

CABLE

DUT GAIN APPROXIMATELY 14dB

ROHDE AND

SCHWARZ

FSEM30

dc1774aa F05

VCC = 4.75V TO 5.25V

DC POWER SUPPLY

GND V+

ASSY U1

FREQUENCY

(MHz)

–A LTC6430AIUF-15 100 TO 300

–B LTC6430AIUF-15 400 TO 1000

–C LTC6431AIUF-15 100 TO 1200

dc1774aaf

DEMO MANUAL DC1774A-A

parts list

ITEM QTY REFERENCE PART DESCRIPTION MANUFACTURER/PART NUMBER

DC1774A-2 Required Circuit Components

1 4 C1, C3, C7, C20 CAP., X7R, 1000pF, 50V, 5%, 0402 AVX, 04025C102JAT2A

2 1 C21 CAP., X7R, 1000pF, 50V, 5%, 0603 AVX, 06035C102JAT2A

3 1 C8 CAP., COG, 62pF, 16V, 2%, 0402 AVX, 0402YA620GAT2A

4 0 C10, C12 CAP., COG, 62pF, 16V, 2%, 0402 OPT

5 0 C11, C13, C16-C19 CAP., X7R, 1000pF, 5%, 0402 OPT

6 1 C22 CAP., X5R, 0.1µF, 10V, 10%, 0603 AVX, 0603ZD104KAT2A

7 2 E3, E6 TESTPOINT, TURRET, 0.064" MILL-MAX, 2308-2-00-80-00-00-07-0

8 0 JP1 HEADER, 2×6, 0.1" OPT

9 0 JP2, JP3 HEADER, 2×4, 0.1" OPT

10 0 J5, J6 CONN., SMA 50Ω EDGE-MOUNTED OPT

11 1 J7 CONN., SMA 50Ω EDGE-MOUNTED JOHNSON, 142-0701-851

12 0 J9 CONN., SMA 50Ω EDGE-MOUNTED OPT

13 2 J11, J18 JACK, BANANA KEYSTONE, 575-4

14 1 L1 INDUCTOR, CHIP, 560nH, 5%, 0603LS-1608 COILCRAFT, 0603LS-561XJLB

15 0 L11, L22 INDUCTOR, CHIP, 1008LS-2520 OPT

16 1 R2 RES., CHIP, 348, 1%, 0402 YAGEO, RC0402FR-07348RL

17 0 R5, R6 RES., CHIP, 348, 1%, 0402 OPT

18 0 R19 RES., CHIP, 0Ω, 5%, 0402 YAGEO, RC0402JR-070RL

DC1774A2-A Required Circuit Components

1 1 DC1774A-2 GENERAL BOM

2 2 C2, C4 CAP., X7R, 1000pF, 50V, 5%, 0402 AVX, 04025C102JAT2A

3 1 C5 CAP., X7R, 1000pF, 50V, 5%, 0603 AVX, 06035C102JAT2A

4 1 C9 CAP., COG, 62pF, 16V, 2%, 0402 AVX, 0402YA620GAT2A

5 2 C14, C15 CAP., X7R, 1000pF, 25V 5%, 0402 AVX, 04023C102JAT2A

6 1 C23 CAP., X5R, 0.1µF, 10V, 10%, 0603 AVX, 0603ZD104KAT2A

7 1 L2 INDUCTOR, CHIP, 560nH, 5%, 0603LS-1608 COILCRAFT, 0603LS-561XJLB

8 1 J8 CONN., SMA 50Ω EDGE-MOUNTED JOHNSON, 142-0701-851

9 0 J10 CONN., SMA 50Ω EDGE-MOUNTED OPT

10 1 R1 RES., CHIP, 348, 1%, 0402 YAGEO, RC0402FR-07348RL

11 2 R3, R4 RES., CHIP, 0Ω, 1/16W, 5%, 0603 YAGEO, RC0603JR-070RL

12 0 R13, R14, R17, R18 RES., CHIP, 0Ω, 1/16W, 5%, 0603 OPT

13 0 T1, T2 XFMR, MINI-CIRCUITS, ADT2-1T+ OPT

14 2 T3, T4 XFMR, 2:1 MINI CIRCUITS, ADT2-1T+

15 1 U1 IC, IF AMP., QFN24UF-4×4 LINEAR TECHNOLOGY, LTC6430AIUF-15

dc1774aaf

DEMO MANUAL DC1774A-A

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.

However, no responsibility is assumed for its use. Linear Technology Corporation makes no representa-

tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.

Figure 6. DC1774A RF/IF AMP/ADC Driver

schematic Diagram

D D

C C

B B

A A

1. ALL RESISTORS ARE IN OHMS, 0402.

ALL CAPACITORS ARE 0402.

2. ALL DNC PINS ON U1 ARE FOR LINEAR USE ONLY.

NOTE: UNLESS OTHERWISE SPECIFIED

CAL IN

CAL OUT

GND

+5V

OPTIONAL CIRCUIT

100-300 MHz

FREQ.

400-1000 MHzLTC6430AIUF-15

ASSY U1

ADT2-1T+

T3, T4

ADTL2-18

OPT

R13,R14,R17,R18

OPT

R3, R4

0 OHM

LTC6430AIUF-15

STUFF

OPT

1008

+IN

-IN

+OUT

-OUT

J10

OPT

560nH

OPTOPT

0.1uF

C23

0.1uF

C14,C15

1000pF, 0402

OPT

OPTOPT

1000pF, 0603

1000pF, 06031000pF, 0402

C2,C4

62pF

OPT

62pF

348

OPT

3481000pF, 0402 560nH

OPT

THIS IS A UNIVERSAL PCB, DESIGNED TO

ACCOMMODATE MULTIPLE VERSIONS OF THE IC.

REFER TO SIMPLIFIED SCHEMATIC IN FIGURE 3 OF

THE DEMO MANUAL.

OPT0 OHMOPTOPT100-1200 MHzLTC6431AIUF-15 STUFF-C

-A

-B

JOHN C.PRODUCTION2 11-09-12

REVISION HISTORY

DESCRIPTION DATEAPPROVEDECO REV

Friday, November 09, 2012

IF AMP/ADC DRIVER

KIM T.

JOHN C.

N/A

LTC643XIUF FAMILY

DEMO CIRCUIT 1774A

SIZE

DATE:

IC NO. REV.

SHEET OF

TITLE:

APPROVALS

PCB DES.

APP ENG.

TECHNOLOGY

Fax: (408)434-0507

Milpitas, CA 95035

Phone: (408)432-1900

1630 McCarthy Blvd.

LTC Confidential-For Customer Use Only

CUSTOMER NOTICE

LINEAR TECHNOLOGY HAS MADE A BEST EFFORT TO DESIGN A

CIRCUIT THAT MEETS CUSTOMER-SUPPLIED SPECIFICATIONS;

HOWEVER, IT REMAINS THE CUSTOMER'S RESPONSIBILITY TO

VERIFY PROPER AND RELIABLE OPERATION IN THE ACTUAL

APPLICATION. COMPONENT SUBSTITUTION AND PRINTED

CIRCUIT BOARD LAYOUT MAY SIGNIFICANTLY AFFECT CIRCUIT

PERFORMANCE OR RELIABILITY. CONTACT LINEAR

TECHNOLOGY APPLICATIONS ENGINEERING FOR ASSISTANCE.

THIS CIRCUIT IS PROPRIETARY TO LINEAR TECHNOLOGY AND

SCHEMATIC

SUPPLIED FOR USE WITH LINEAR TECHNOLOGY PARTS.

SCALE = NONE

www.linear.com

VCC

1000pF

SMA

348

C23

0.1uF

C11

1000pF

560nH

R19

OPT

C13

1000pF

C18

1000pF

R17

0603

1000pF

JP2

HD2X4-100

R14

0603

C14

1000pF

L11

OPT

R13

0603

SMA

OPT

62pF

JP3

HD2X4-100

C21

1000pF

J11

+5V

1000pF

L22

OPT

C19

1000pF

348

C16

1000pF

R18

0603

SMA

SEE BOM

62pF

C22

0.1uF

C17

1000pF

SMA

C10

62pF

0603

C12

62pF

C15

1000pF

348

JP1

HD2X6-100

9 10

11 12

SEE BOM

10 21

DNC

GND

DNC

+IN

DNC

GND

DNC DNC

DNC

GND

VCC

DNC

+OUT

T_DIODE

DNC

-IN

VCC

DNC

-OUT

DNC

GND

0603

1000pF

J18

GND

348

J10

SMA

1000pF

C20

1000pF

560nH

1000pF

dc1774aaf

DEMO MANUAL DC1774A-A

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com

 LINEAR TECHNOLOGY CORPORATION 2013

LT 0113 • PRINTED IN USA

DEMONSTRATION BOARD IMPORTANT NOTICE

Linear Technology Corporation (LT C ) provides the enclosed product(s) under the following AS IS conditions:

This demonstration board (DEMO BOARD) kit being sold or provided by Linear Technology is intended for use for ENGINEERING DEVELOPMENT

OR EVALUATION PURPOSES ONLY and is not provided by LT C for commercial use. As such, the DEMO BOARD herein may not be complete

in terms of required design-, marketing-, and/or manufacturing-related protective considerations, including but not limited to product safety

measures typically found in finished commercial goods. As a prototype, this product does not fall within the scope of the European Union

directive on electromagnetic compatibility and therefore may or may not meet the technical requirements of the directive, or other regulations.

If this evaluation kit does not meet the specifications recited in the DEMO BOARD manual the kit may be returned within 30 days from the date

of delivery for a full refund. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY THE SELLER TO BUYER AND IS IN LIEU

OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS

FOR ANY PARTICULAR PURPOSE. EXCEPT TO THE EXTENT OF THIS INDEMNITY, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR

ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES.

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arising from the handling or use of the goods. Due to the open construction of the product, it is the user’s responsibility to take any and all

appropriate precautions with regard to electrostatic discharge. Also be aware that the products herein may not be regulatory compliant or

agency certified (FCC, UL, CE, etc.).

No License is granted under any patent right or other intellectual property whatsoever. LT C assumes no liability for applications assistance,

customer product design, software performance, or infringement of patents or any other intellectual property rights of any kind.

LT C currently services a variety of customers for products around the world, and therefore this transaction is not exclusive.

Please read the DEMO BOARD manual prior to handling the product. Persons handling this product must have electronics training and

observe good laboratory practice standards. Common sense is encouraged.

This notice contains important safety information about temperatures and voltages. For further safety concerns, please contact a LT C applica-

tion engineer.

Mailing Address:

Linear Technology

1630 McCarthy Blvd.

Milpitas, CA 95035