Electrical characteristics (continued) – Rainbow Electronics MAX1400 User Manual
Page 6
MAX1400
+5V, 18-Bit, Low-Power, Multichannel,
Oversampling (Sigma-Delta) ADC
6
_______________________________________________________________________________________
Note 1:
Nominal gain is 0.98. This ensures a full-scale input voltage may be applied to the part under all conditions without caus-
ing saturation of the digital output data.
Note 2:
Positive Full-Scale Error includes zero-scale errors (unipolar offset error or bipolar zero error) and applies to both unipolar
and bipolar input ranges. This error does not include the nominal gain of 0.98.
Note 3:
Full-Scale Drift includes zero-scale drift (unipolar offset drift or bipolar zero drift) and applies to both unipolar and bipolar
input ranges.
Note 4:
Gain Error does not include zero-scale errors. It is calculated as (full-scale error - unipolar offset error) for unipolar ranges
and as (full-scale error - bipolar zero error) for bipolar ranges. This error does not include the nominal gain of 0.98.
Note 5:
Gain-Error Drift does not include unipolar offset drift or bipolar zero drift. It is effectively the drift of the part if zero-scale
error is removed.
Note 6:
Use of the offset DAC does not imply that any input may be taken below AGND.
Note 7:
Additional noise added by the offset DAC is dependent on the filter cutoff, gain, and DAC setting. No noise is added for a
DAC code of 0000.
Note 8:
Guaranteed by design or characterization; not production tested.
Note 9:
The input voltage must be within the Absolute Input Voltage Range specification.
Note 10:
All AIN and REFIN pins have identical input structures. Leakage is production tested only for the AIN3, AIN4, AIN5,
CALGAIN, and CALOFF inputs.
Note 11:
The dynamic load presented by the MAX1400 analog inputs for each gain setting is discussed in detail in the
Switching
Network
section
.
Values are provided for the maximum allowable external series resistance. Note that this value does not
include any additional capacitance added by the user to the MUXOUT_ or ADCIN_ pins.
Note 12:
The input voltage range for the analog inputs is with respect to the voltage on the negative input of its respective differen-
tial or pseudo-differential pair. Table 5 shows which inputs form differential pairs.
Note 13:
V
REF
= V
REFIN+
- V
REFIN-
.
Note 14:
These specifications apply to CLKOUT only when driving a single CMOS load.
Note 15:
The burn-out currents require a 500mV overhead between the analog input voltage and both V+ and AGND to operate
correctly.
ELECTRICAL CHARACTERISTICS (continued)
(V+ = +5V ±5%, V
DD
= +2.7V to +5.25V, V
REFIN+
= +2.50V, REFIN- = AGND, f
CLKIN
= 2.4576MHz, T
A
= T
MIN
to T
MAX
, unless other-
wise noted. Typical values are at T
A
= +25°C.)
2.4576MHz
1.024MHz
Buffers off
Buffers off
Buffers on
2.4576MHz
1.024MHz
2.43
3.60
Buffers off
Buffers off
Buffers on
Normal mode,
MF1 = 0,
MF0 = 0
4.23
5.75
2.43
3.75
Buffers on
3.70
Buffers on
2X mode,
MF1 = 0,
MF0 = 1
7.4
10.0
CONDITIONS
3.50
5.25
1.88
2.4576MHz
1.024MHz
Buffers off
Buffers off
Buffers on
2.4576MHz
1.024MHz
6.85
Buffers off
Buffers off
Buffers on
4X mode,
MF1 = 1,
MF0 = 0
25.8
33.0
10.8
14.0
Buffers on
25.2
Buffers on
8X mode,
MF1 = 1,
MF0 = 1
mW
26.7
34.0
PD
Power Dissipation
11.7
15.0
10.2
2.95
(Note 18)
10
100
µW
Standby Power Dissipation
1.45
2.55
UNITS
MIN
TYP
MAX
SYMBOL
PARAMETER
5V POWER DISSIPATION
(V+ = V
DD
= +5V, digital inputs = 0 or V
DD
, external CLKIN, burn-out currents disabled, X2CLK = 0,
CLK = 0 for 1.024MHz, CLK = 1 for 2.4576MHz.)