MAX11135_V1 Datasheet, PDF(34/40 Page) Maxim Integrated Products – 500ksps, Low-Power, Serial 12-/10-/8-Bit,4-/8-/16-Channel ADCs

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MAX11135_V1 Datasheet, PDF (34/40 Pages) Maxim Integrated Products – 500ksps, Low-Power, Serial 12-/10-/8-Bit,4-/8-/16-Channel ADCs

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MAX11135âMAX11143

500ksps, Low-Power, Serial 12-/10-/8-Bit,

4-/8-/16-Channel ADCs

SCLK

DIN

DOUT

WRITE SampleSet REGISTER

DEFINE SEQ_LENGTH

ENTRY 1 ENTRY 2

ENTRY N = (SEQ_LENGTH)

LOAD SampleSet PATTERN

TIME BETWEEN CS FALLING AND

RISING EDGE DEPENDS ON SEQ_LENGTH

WRITE ADC MODE CONTROL

OR CONTINUE WITH ADDITIONAL

CONFIGURATION SETTINGS

Figure 10. SampleSet Timing Diagram

Upon receiving the SampleSet pattern, the user can

set the ADC Mode Control register to begin the conver-

sion process where data readout begins with the first

SampleSet entry. While the last conversion result is read,

the ADC can be instructed to enter AutoShutdown, if

desired. If the user wishes to change the SampleSet

length, a new pattern must be loaded into the ADC as

described in Figure 10.

Applications Information

How to Program Modes

1) Configure the ADC (set the MSB on DIN to 1).

2) Program ADC mode control (set the MSB on DIN to 0)

to begin the conversion process or to control power

management features.

â¢ If ADC mode control is written during a conversion

sequence, the ADC finishes the present conver-

sion and at the next falling edge of CS initiates its

new instruction.

â¢ If configuration data (MSB on DIN is a 1) is written

during a conversion sequence, the ADC finishes

the present conversion in the existing scan mode.

However, data on DOUT is not valid in following

frames until a new ADC mode control instruction

is coded.

Programming Sequence Flow Chart

See Figure 11 for programming sequence.

Layout, Grounding, and Bypassing

For best performance, use PCBs with a solid ground

plane. Ensure that digital and analog signal lines are

separated from each other. Do not run analog and digital

(especially clock) lines parallel to one another or digital

lines underneath the ADC package. Noise in the VDD,

OVDD, and REF affects the ADCâs performÂ ance. Bypass

the VDD, OVDD, and REF to ground with 0.1FF and 10FF

bypass capacitors. Minimize capacitor lead and trace

lengths for best supply-noise rejection.

Choosing an Input Amplifier

It is important to match the settling time of the input

amplifier to the acquisition time of the ADC. The converÂ

sion results are accurate when the ADC samples the

input signal for an interval longer than the input signalâs

worst-case settling time. By definition, settling time is

the interval between the application of an input voltage

step and the point at which the output signal reaches

and stays within a given error band centered on the

resulting steady-state amplifier output level. The ADC

input sampling capacitor charges during the sampling

cycle, referred to as the acquisition period. During this

acquisition period, the settling time is affected by the

input resistance and the input sampling capacitance.

This error can be estimated by looking at the settling

of an RC time constant using the input capacitance

and the source impedance over the acquisition time

period. Figure 13 shows a typical application circuit. The

MAX4430, offering a settling time of 37ns at 16-bit reso-

lution, is an excellent choice for this application. See the

THD vs. Input Resistance graph in the Typical Operating

Characteristics.

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