SLAS887 Data sheet

SLAS887C September 2014 – March 2021

PRODUCTION DATA

Package Options

Mechanical Data (Package|Pins)

PW|28
- MPDS364
RHB|32
- MPQF130D

Thermal pad, mechanical data (Package|Pins)

RHB|32
- QFND257K

Orderable Information

8.7.7.6 SD24 Performance, External Reference (SD24REFS = 0, SD24OSRx = 256)

external reference voltage is 1.2 V., over operating free-air temperature range (unless otherwise noted)

PARAMETER		TEST CONDITIONS		V_CC	MIN	TYP	MAX	UNIT
SINAD	Signal-to-noise + distortion ratio	SD24GAINx = 1	f_IN = 50 Hz⁽¹⁾	3 V		91		dB
		SD24GAINx = 2				90
		SD24GAINx = 4				88
		SD24GAINx = 8				83
		SD24GAINx = 16				77
THD	Total harmonic distortion	SD24GAINx = 1	f_IN = 50 Hz⁽¹⁾	3 V		100		dB
		SD24GAINx = 8				95
		SD24GAINx = 16				90
SFDR	Spurious-free dynamic range	SD24GAINx = 1	f_IN = 50 Hz⁽¹⁾	3 V		100		dB
		SD24GAINx = 8				95
		SD24GAINx = 16				90
INL	Integral nonlinearity, end-point fit	SD24GAINx: 1, 8, 16		3 V	–0.003		0.003	% FSR
G	Nominal gain	SD24GAINx = 1		3 V		1
		SD24GAINx = 2				2
		SD24GAINx = 4				4
		SD24GAINx = 8				8
		SD24GAINx = 16				16
E_G	Gain error	SD24GAINx: 1, 2, 4, 8, 16		3 V	–1%		+1%
ΔE_G/ ΔT	Gain error temperature coefficient	SD24GAINx: 1, 8, 16		3 V			10	ppm/°C
E_OS	Offset error	SD24GAINx = 1		3 V			4	mV
E_OS	Offset error	SD24GAINx = 16		3 V			2	mV
ΔEOS/ΔT	Offset error temperature coefficient	SD24GAINx = 1		3 V		±5	±25	ppm FSR/°C
ΔEOS/ΔT	Offset error temperature coefficient	SD24GAINx = 16		3 V		±3	±10	ppm FSR/°C
CMRR,50Hz	Common-mode rejection ratio at 50 Hz	SD24GAINx = 1, Common-mode input signal: V_ID = 928 mV, f_IN = 50 Hz		3 V		–55		dB
CMRR,50Hz	Common-mode rejection ratio at 50 Hz	SD24GAINx = 16, Common-mode input signal: V_ID = 58 mV, f_IN = 50 Hz		3 V		–60		dB
AC PSRR	AC power supply rejection ratio	SD24GAINx: 1, V_CC = 3 V ±50 mV × sin(2π × f_VCC × t), f_VCC = 50 Hz, Inputs grounded (no analog signal applied)		3 V		–90		dB
		SD24GAINx: 8, V_CC = 3 V ±50 mV × sin(2π × f_VCC × t), f_VCC = 50 Hz, Inputs grounded (no analog signal applied)		3 V		–95
		SD24GAINx: 16, V_CC = 3 V ±50 mV × sin(2π × f_VCC × t), f_VCC = 50 Hz, Inputs grounded (no analog signal applied)		3 V		–95
XT	Crosstalk between converters	Crosstalk source: SD24GAINx = 1, Sine-wave with maximum possible V_PP, f_IN = 50 Hz or 100 Hz, Converter under test: SD24GAINx = 1		3 V		–120		dB
		Crosstalk source: SD24GAINx = 1, Sine-wave with maximum possible V_PP, f_IN = 50 Hz or 100 Hz, Converter under test: SD24GAINx = 8				–110
		Crosstalk source: SD24GAINx = 1, Sine-wave with maximum possible V_PP, f_IN = 50 Hz or 100 Hz, Converter under test: SD24GAINx = 16				–110

(1) The following voltages are applied to the SD24 inputs:
V_I,A+(t) = 0 V + V_PP/2 × sin(2π × f_IN × t)
V_I,A–(t) = 0 V – V_PP/2 × sin(2π × f_IN × t)
resulting in a differential voltage of V_ID = V_IN,A+(t) – V_IN,A–(t) = V_PP × sin(2π × f_IN × t) with V_PP being selected as the maximum value allowed for a given range (according to SD24 input range).