Datasheet

ManualsBrandsLINEAR TECHNOLOGY ManualsData collecting ICsData acquisition IC - AD converter (ADC) External , Internal QFN 32

LTC2351-14

235114fb

235114 F03

FREQUENCY (Hz)

–100

CMRR (dB)

–60

–20

–40

–80

10k 100k 1M 10M 100M 1G

–120

100 1k

INPUT VOLTAGE (V)

2'S COMPLEMENT OUTPUT CODE

235114 F05

011...111

011...110

011...101

100...000

100...001

100...010

FS – 1LSB–FS

INPUT VOLTAGE (V)

STRAIGHT BINARY OUTPUT CODE

235114 F04

111...111

111...110

111...101

000...000

000...001

000...010

FS – 1LSB0

APPLICATIONS INFORMATION

Figure 5 shows the ideal input/output characteristics for

the LTC2351-14 in bipolar mode (BIP = HIGH). The code

transitions occur midway between successive integer LSB

values (i.e., 0.5LSB, 1.5LSB, 2.5LSB, FS – 1.5LSB). The

output code is 2’s complement with 1LSB = 2.5V/16384 =

153μV for the LTC2351-14. The LTC2351-14 has 0.7 LSB

RMS of gaussian white noise.

INPUT SPAN VERSUS REFERENCE VOLTAGE

The differential input range has a unipolar voltage span

that equals the difference between the voltage at the

reference buffer output V

REF

(Pin 23) and the voltage at

ground. The differential input range of the ADC is 0V to

2.5V when using the internal reference. The internal ADC

is referenced to these two nodes. This relationship also

holds true with an external reference.

DIFFERENTIAL INPUTS

The ADC will always convert the difference of CH

minus

–

, independent of the common mode voltage at any pair

of inputs. The common mode rejection holds up at high

frequencies (see Figure 3.) The only requirement is that

both inputs not go below ground or exceed V

Figure 3. CMRR vs Frequency

Integral nonlinearity errors (INL) and differential nonlinear-

ity errors (DNL) are largely independent of the common

mode voltage. However, the offset error will vary. DC CMRR

is typically better than –90dB.

Figure 4 shows the ideal input/output characteristics for

the LTC2351-14 in unipolar mode (BIP = LOW). The code

transitions occur midway between successive integer LSB

values (i.e., 0.5LSB, 1.5LSB, 2.5LSB, FS – 1.5LSB). The

output code is straight binary with 1LSB = 2.5V/16384 =

153μV for the LTC2351-14. The LTC2351-14 has 0.7 LSB

RMS of gaussian white noise.

Figure 5. LTC2351-14 Transfer Characteristic

in Bipolar Mode (BIP = HIGH)

Figure 4. LTC2351-14 Transfer Characteristic

in Unipolar Mode (BIP = LOW)