max555ccbtd Maxim Integrated Products, Inc., max555ccbtd Datasheet - Page 8

max555ccbtd

Manufacturer Part Number

max555ccbtd

Description

Max555 300msps, 12-bit Dac With Complementary Voltage Outputs

Manufacturer

Maxim Integrated Products, Inc.

Datasheet

1.MAX555CCBTD.pdf (12 pages)

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300Msps, 12-Bit DAC with

Complementary Voltage Outputs

possible latchup. Appropriate decoupling is needed to

prevent digital-section current spikes from affecting the

analog section (Figure 4).

It is recommended that a multilayer PC board be used,

containing a solid ground and power planes. All analog

and digital ground pins must be connected directly to

the analog ground plane at the MAX555, preferably with

a “star connection” at the LGND pins (15 and 16).

High-speed ECL inputs, as well as the output from the

MAX555, should employ good transmission-line tech-

niques, with terminations close to the device pins.

Separate power-supply buses for analog and digital

power supplies are recommended as good general

practice. Best results will be achieved by bypassing

the device pins with high-quality ceramic chip capaci-

tors connected physically close to the pins.

The MAX555 uses an internal op-amp circuit to buffer the

reference current. The input to the op amp may be driv-

en with an external current source of 1.25mA or a 1V

external voltage reference. The reference input is the REF

pin. The input impedance to the op amp is 800Ω. As

shown in Figure 1, REF/2 is brought out externally with

400Ω of impedance to the op amp. These reference

inputs can be used to vary the full-scale output for high-

speed multiplying applications. ROFFSET must be con-

nected to analog ground. In addition, a 0.1µF capacitor

should be connected from REF/2 to analog ground to

reduce reference current noise.

The analog outputs are laser trimmed to 50Ω. They can

be used either as a voltage drive with 50Ω impedance, or

to drive into a virtual null using a transimpedance amplifi-

er. Greater speed is achieved driving into 50Ω loads.

The differential outputs of the MAX555 may be used to

drive a balun for conversion to a single-ended output,

while at the same time greatly reducing the second-har-

monic content of the output.

The Typical Operating Characteristics graphs show the

MAX555’s performance when used in direct digital synthe-

sis (DDS) applications for generating RF sine waves. The

first six graphs show the MAX555’s spurious-free dynam-

ic range (SFDR) for clock frequencies of 50MHz to

300MHz at various output frequencies. The seventh

graph displays the SFDR for clock frequencies from

50MHz to 350MHz while producing an output frequen-

cy of about 1/16 the clock frequency.

_______________________________________________________________________________________

Applications Information

Dynamic Performance

Reference Input

Outputs

The last two graphs show the MAX555’s third and sec-

ond harmonic distortion while producing an output fre-

quency of about 1/5 f

100MHz to 300MHz as a function of the reference volt-

age. The third harmonic content of the output can be

reduced at clock frequencies below about 200MHz by

reducing the reference voltage from its 1.000V nominal

value. At clock frequencies above about 200MHz, the

output’s third harmonic content is dominated by cou-

pling from the high-speed digital inputs to the output.

Reducing the reference voltage at these high clock

rates increases the third harmonic distortion in the out-

put, since the carrier amplitude drops but the third har-

monic level remains relatively constant.

The second harmonic distortion of the outputs is shown

as a function of clock frequency and reference voltage.

It is relatively constant for clock frequencies below

about 200MHz at different V

third harmonic distortion, however, the second harm-

onic distortion also increases at clock frequencies over

200MHz for lower V

the input logic levels and/or decreasing the rise time of

the digital signals can improve the output’s harmonic

content. Some experimentation may be required to

optimize the MAX555’s performance for a particular

application.

Figure 3 shows the spectrum analyzer plots of the

MAX555 when used in DDS applications. These plots

show the MAX555’s output spectrum at clock frequen-

cies from 50MHz to 300MHz while producing various

output frequencies. Observing the output spectrum

while adjusting the reference voltage or varying the

logic levels is a sensitive method of optimizing MAX555

performance. The plots shown were obtained with a

0.75V reference voltage level and 500mV ECL logic

swings.

Figure 4 shows a typical connection. With VOUT used

to drive a 50Ω line, the unused complementary output,

VOUT, should also be terminated to 50Ω. A 1V refer-

ence voltage at REF gives a -0.5V full-scale voltage at

VOUT (when doubly terminated with 50Ω on the out-

put). Because some loads may represent a complex

impedance, be sure to match the output impedance

with the load. Mismatching the impedances can cause

reflections that will affect AC-performance parameters.

In all applications, the LOOPCRNT pin is always con-

nected to AGND, and compensation capacitors are

connected to pins ALTCOMPC, ALTCOMPIB, and

LBIAS. The LBIAS compensation is recommended for

non-multiplying applications.

REF

CLK

values. Reducing the swing of

for clock frequencies from

REF

Typical Application

values. As with the

max555ccbtd Maxim Integrated Products, Inc., max555ccbtd Datasheet - Page 8

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