DC2078A Datasheet DC2078A | P4-P6

dc2078af

DEMO MANUAL DC2078A

L3, L4, C19 and C20 are optional parts. They are for ad-

ditional matching c

omponents when further optimization to

a lower or wider frequency range applications is required.

Table 2 shows the function of each input and output on

the board.

Additional Information

As with any RF device, minimizing ground inductance is

critical. Care should be taken with the board layout because

of the 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 lower the inductance

to ground. 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 T_DIODE Pin (Turret E3) can be forward biased to

ground with 1mA of current. The measured voltage will

be an indicator of the chip junction temperature (TJ).

Table 3. The LTC643X-YY Amplifier Family and Corresponding Application Demo Boards

DEMO BOARD NUMBER

FREQUENCY RANGE

(MHz) NOTES/APPLICATIONS

BOARD’S IN/OUT

IMPEDANCE AMPLIFIER

AMPLIFIER’S

IMPEDANCE

DC1774A-A 50 to 350 Low Frequency 50Ω LTC6430-15 Differential 100Ω

DC1774A-B 400 to 1000 Mid Frequency 50Ω LTC6430-15 Differential 100Ω

DC1774A-C 100 to 1200 Wide Frequency 50Ω LTC6431-15 Single-ended 50Ω

DC2032A 50 to 1000 Cable Infrastructure 75Ω LTC6430-15 Differential 100Ω

DC2077A 100 to 1200 Wide Frequency 50Ω LTC6431-20 Single-ended 50Ω

DC2153A 700 to 1700 High Frequency 50Ω LTC6430-15 Differential 100Ω

DC2090A 50 to 1200 Power Doubler 50Ω Dual LTC6430-15 Differential 50Ω

DC2076A-A 50 to 350 Low Frequency 50Ω LTC6430-20 Differential 100Ω

DC2076A-B 350 to 1000 Mid Frequency 50Ω LTC6430-20 Differential 100Ω

DC2078A 50 to 1000 Cable Infrastructure 75Ω LTC6430-20 Differential 100Ω

OPERATION

Please note that a number of DNC pins are connected on

the demo board. These connections are not necessary for

normal operation, however, failure to float these pins may

impair the operation of the device.

Table 3 shows the LTC643X-YY amplifier series and its

associated demo boards. Each demo board lists the typical

working frequency range and the input and output imped

ance of the amplifiers.

Setup Signal Sources and Spectrum Analyzer

The

LTC6430-20 is an amplifier with

high linearity

perfor-

mance. Therefore, the o

utput intermodulation products are

very low. Even using high dynamic range test equipment,

Third-Order Intercept (IP3) measurements can drive test

setups to their limits. Consequently, accurate measure

ment of IP3 for a low distortion IC such as the LTC6430-20

requires

certain precautions to be observed in the test

setup as well as in the testing procedure.

dc2078af

DEMO MANUAL DC2078A

Setup Signal Sources

Figure 4 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 below:

High performance signal generators 1 and 2 (HP8644A)

are used. These suggested generators have low har

monic distortion and very low phase noise.

b. High linearity amplifiers are used to improve the reverse

isolation. This prevents cross talk between the two

signal generators and provides higher output power.

c. A low pass filter is used to suppress the harmonic content

from interfering with the test signal. Note that second

order inputs can “mix” with the fundamental frequency

to form intermodulation (IM) products of their own. We

suggest filtering the harmonics to –50dBc orbetter.

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 improved VSWR and

isolation, the H-9 signal combiner from MA/COM is an

alternative 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 further support isolation of the two input

signal sources. They also reduce reflections and promote

maximum power transfer with wideband impedance

matching.

Setup the Spectrum Analyzer

a. Adjust the spectrum analyzer for maximum possible

resolution of the intermodulation products’ amplitude

in dBc. A narrower resolution bandwidth will take a

longer time to sweep.

b. Optimize the dynamic range of the spectrum analyzer

by adjusting the input attenuation. First increase the

spectrum analyzer’s input attenuation (normally in

steps of 5dB or 10dB). If the IM product levels decrease

when the input attenuation is increased, then the input

power level is too high for the spectrum analyzer to

make a valid measurement. Most likely, the spectrum

analyzer’s 1st mixer was overloaded and producing its

own IM products. If the IM reading holds constant with

increased input attenuation, then a sufficient amount

of attenuation was present. Adding too much attenua

tion will bury the intended IM signal in the noise floor.

Therefore,

select just enough attenuation to achieve a

stable and valid measurement.

c. In order to achieve this valid measurement result, the

test system must have lower total distortion than the

DUT’

s intermodulation.

For example, to measure a

47dBm OIP3, the measured intermodulation products

will be –92dBc below an –18dBm/tone input level and

the test system must have intermodulation products

approximately –98dBc or better. For best results,

the IM products and noise floor should measure at

least–102dBc before connecting the DUT.

OPERATION

dc2078af

DEMO MANUAL DC2078A

Demo circuit 2078A can be set up to evaluate the perfor-

mance of the LTC6430-20. Refer to Figure 4 for proper

equipment connections and follow the procedure below:

o -Tone Measurement:

Connect all test equipment as suggested in Figure 4.

1. The power labels of “VCC 4.75V-5.25V” and GND di

rectly correspond

to the power supply. Typical current

consumption of the LTC6430-20 is about 170mA.

2. Apply two independent signals f1 and f2 from signal

generator 1 and signal generator 2 at 600MHz and

601MHz, while setting the amplitude to –18dBm/tone

at the demo board input (J1).

3. Monitor the output tone level on the spectrum analyzer.

Adjust the signal generator levels such that the output

power measures +1dBm/tone at the amplifier output

J2, after correcting for external cable losses, minimum

loss matching pads and attenuations.

QUICK START PROCEDURE

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 599MHz and 602MHz, respectively. The

measurement levels should be approximately –92dBc;

+47dBm is typical OIP3 performance for the LTC6430-20

at 600MHz.

The OIP3 calculation is:

OIP3 = POUT + ∆IMD3/2

Where:

POUT is the lower output signal power of the funda-

mental products.

∆IMD3 = POUT – PIM3; PIM3 is the higher Third-Order

intermodulation product.

Single-tone Measurement

5. Continue with step 4 above, turn off one signal source

to measure gain and harmonic distortions.

P1-P3 P4-P6 P7-P9 P10-P10

DC2078A

Mfr. #:

Buy DC2078A

Manufacturer:

Analog Devices Inc.

Description:

RF Development Tools LTC6430-20 Demo Board - 50MHz TO 1000MHz

Lifecycle:

New from this manufacturer.

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DC2078A