MAX1316 Datasheet, PDF(22/27 Page) Maxim Integrated Products – 8-/4-/2-Channel, 14-Bit, Simultaneous-Sampling ADCs with 10V, 5V, and 0 to +5V Analog Input Ranges

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MAX1316 Datasheet, PDF (22/27 Pages) Maxim Integrated Products – 8-/4-/2-Channel, 14-Bit, Simultaneous-Sampling ADCs with 10V, 5V, and 0 to +5V Analog Input Ranges

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8-/4-/2-Channel, 14-Bit, Simultaneous-Sampling ADCs

with Â±10V, Â±5V, and 0 to +5V Analog Input Ranges

0x3FFF

0x3FFE

0x3FFD

0x3FFC

0x2001

0x2000

0x1FFF

2 x VREF

0x0003

0x0002

0x0001

0x0000

1 LSB = 2 x VREF

214

8192

8190 8194

(MSV)

INPUT VOLTAGE (LSBs)

16,381 16,383

Figure 11. 0 to +5V Unipolar Transfer Function

The input range is centered about VMSV, which is inter-

nally set to +2.500V. For a custom midscale voltage,

drive REFMS with an external voltage source and MSV

will follow REFMS. Noise present on MSV or REFMS

directly couples into the ADC result. Use a precision,

low-drift voltage reference with adequate bypassing to

prevent MSV from degrading ADC performance. For

maximum FSR, be careful not to violate the absolute

maximum voltage ratings of the analog inputs when

choosing VMSV. Determine the input voltage as a func-

tion of VREF, VMSV, and the output code in decimal

using the following equation:

( ) VCH_ = LSB Ã CODE10 + VMSV - 2.500V

Definitions

Integral Nonlinearity

Integral nonlinearity (INL) is the deviation of the values

on an actual transfer function from a straight line. For

these devices, this straight line is a line drawn between

the end points of the transfer function, once offset and

gain errors have been nullified.

Differential Nonlinearity

Differential nonlinearity (DNL) is the difference between

an actual step width and the ideal value of 1 LSB. For

these devices, the DNL of each digital output code is

measured and the worst-case value is reported in the

Electrical Characteristics table. A DNL error specifica-

tion of less than Â±1 LSB guarantees no missing codes

and a monotonic transfer function.

Unipolar Offset Error

For the unipolar MAX1316/MAX1317/MAX1318, the ideal

zero-scale transition from 0x0000 to 0x0001 occurs at

1 LSB (see Figure 11). The unipolar offset error is the

amount of deviation between the measured zero-scale

transition point and the ideal zero-scale transition point.

Bipolar Offset Error

For the bipolar MAX1320/MAX1321/MAX1322/

MAX1324/MAX1325/MAX1326, the ideal zero-point tran-

sition from 0x3FFF to 0x0000 occurs at MSV, which is

usually connected to ground (see Figures 9 and 10).

The bipolar offset error is the amount of deviation

between the measured zero-point transition and the

ideal zero-point transition.

Gain Error

The ideal full-scale transition from 0x1FFE to 0x1FFF

occurs at 1 LSB below full scale (see the Transfer

Functions section). The gain error is the amount of devi-

ation between the measured full-scale transition point

and the ideal full-scale transition point, once offset error

has been nullified.

Signal-to-Noise Ratio

For a waveform perfectly reconstructed from digital

samples, signal-to-noise ratio (SNR) is the ratio of the

full-scale analog input (RMS value) to the RMS quanti-

zation error (residual error). The ideal, theoretical mini-

mum analog-to-digital noise is caused by quantization

noise error only and results directly from the ADCâs res-

olution (N bits):

SNR = (6.02 Ã N + 1.76)dB

where N = 14 bits.

In reality, there are other noise sources besides quanti-

zation noise: thermal noise, reference noise, clock jitter,

etc. SNR is computed by taking the ratio of the RMS

signal to the RMS noise, which includes all spectral

components minus the fundamental, the first five har-

monics, and the DC offset.

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