adc14v155lfeb National Semiconductor Corporation, adc14v155lfeb Datasheet - Page 17

adc14v155lfeb

Manufacturer Part Number

adc14v155lfeb

Description

14-bit, 155 Msps, 1.1 Ghz Bandwidth A/d Converter With Lvds Outputs

Manufacturer

National Semiconductor Corporation

Datasheet

1.ADC14V155LFEB.pdf (22 pages)

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2.1.2 Driving the Analog Inputs

The V

ternal sample-and-hold circuit which consists of an analog

switch followed by a switched-capacitor amplifier. The analog

inputs are connected to the sampling capacitors through

NMOS switches, and each analog input has parasitic capac-

itances associated with it.

When the clock is high, the converter is in the sample phase.

The analog inputs are connected to the sampling capacitor

through the NMOS switches, which causes the capacitance

at the analog input pins to appear as the pin capacitance plus

the internal sample and hold circuit capacitance (approxi-

mately 9 pF). While the clock level remains high, the sampling

capacitor will track the changing analog input voltage. When

the clock transitions from high to low, the converter enters the

hold phase, during which the analog inputs are disconnected

from the sampling capacitor. The last voltage that appeared

at the analog input before the clock transition will be held on

the sampling capacitor and will be sent to the ADC core. The

capacitance seen at the analog input during the hold phase

appears as the sum of the pin capacitance and the parasitic

capacitances associated with the sample and hold circuit of

each analog input (approximately 6 pF). Once the clock signal

transitions from low to high, the analog inputs will be recon-

nected to the sampling capacitor to capture the next sample.

Usually, there will be a difference between the held voltage

on the sampling capacitor and the new voltage at the analog

input. This will cause a charging glitch that is proportional to

the voltage difference between the two samples to appear at

the analog input pin. The input circuitry must be fast enough

to allow the sampling capacitor to settle before the clock sig-

nal goes low again, as incomplete settling can degrade the

SFDR performance.

A single-ended to differential conversion circuit is shown in

Figure 4. A transformer is preferred for high frequency input

signals. Terminating the transformer on the secondary side

provides two advantages. First, it presents a real broadband

impedance to the ADC inputs and second, it provides a com-

mon path for the charging glitches from each side of the

differential sample-and-hold circuit.

One short-coming of using a transformer to achieve the sin-

gle-ended to differential conversion is that most RF trans-

formers have poor low frequency performance. A differential

amplifier can be used to drive the analog inputs for low fre-

quency applications. The amplifier must be fast enough to

settle from the charging glitches on the analog input resulting

from the sample-and-hold operation before the clock goes

high and the sample is passed to the ADC core.

The SFDR performance of the converter depends on the ex-

ternal signal conditioning circuity used, as this affects how

quickly the sample-and-hold charging glitch will settle. An ex-

ternal resistor and capacitor network as shown in Figure 4

should be used to isolate the charging glitches at the ADC

input from the external driving circuit and to filter the wideband

noise at the converter input. These components should be

+ and the V

− V

+ V

REF

− inputs of the ADC14V155 have an in-

+ V

− V

−

REF

TABLE 1. Input to Output Relationship

00 0000 0000 0000

01 0000 0000 0000

10 0000 0000 0000

11 0000 0000 0000

11 1111 1111 1111

Binary Output

placed close to the ADC inputs because the analog input of

the ADC is the most sensitive part of the system, and this is

the last opportunity to filter that input. For Nyquist applications

the RC pole should be at the ADC sample rate. The ADC input

capacitance in the sample mode should be considered when

setting the RC pole. For wideband undersampling applica-

tions, the RC pole should be set at about 1.5 to 2 times the

maximum input frequency to maintain a linear delay re-

sponse.

2.1.3 Input Common Mode Voltage

The input common mode voltage, V

of 1.4V to 1.6V and be a value such that the peak excursions

of the analog signal do not go more negative than ground or

more positive than 2.6V. It is recommended to use V

45) as the input common mode voltage.

2.2 Reference Pins

The ADC14V155 is designed to operate with an internal 1.0V

reference, or an external 1.0V reference, but performs well

with external reference voltages in the range of 0.9V to 1.1V.

The internal 1.0 Volt reference is the default condition when

no external reference input is applied to the V

age in the range of 0.9V to 1.1V is applied to the V

then that voltage is used for the reference. The V

should always be bypassed to ground with a 0.1 µF capacitor

close to the reference input pin. Lower reference voltages will

decrease the signal-to-noise ratio (SNR) of the ADC14V155.

Increasing the reference voltage (and the input signal swing)

beyond 1.1V may degrade THD for a full-scale input, espe-

cially at higher input frequencies.

It is important that all grounds associated with the reference

voltage and the analog input signal make connection to the

ground plane at a single, quiet point to minimize the effects of

noise currents in the ground path.

The Reference Bypass Pins (V

available for bypass purposes. All these pins should each be

bypassed to ground with a 0.1 µF capacitor. A 0.1 µF and a

10 µF capacitor should be placed between the V

pins, as shown in Figure 4. This configuration is necessary to

avoid reference oscillation, which could result in reduced SF-

DR and/or SNR. V

temperature stable 1.5V reference. The remaining pins

should not be loaded.

Smaller capacitor values than those specified will allow faster

recovery from the power down and sleep modes, but may re-

sult in degraded noise performance. Loading any of these

pins, other than V

The nominal voltages for the reference bypass pins are as

follows:

= V

= 1.5 V

2’s Complement Output

10 0000 0000 0000

11 0000 0000 0000

00 0000 0000 0000

01 0000 0000 0000

01 1111 1111 1111

+ V

− V

REF

, may result in performance degradation.

/ 2

may be loaded to 1mA for use as a

, V

, should be in the range

Negative Full-Scale

Positive Full-Scale

, and V

Mid-Scale

REF

pin. If a volt-

www.national.com

) are made

and V

REF

(pin

pin,

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