The LMP90080-Q1 is a highly integrated, multi-channel, low-power 16-bit Sensor AFE. The devices feature a precision, 16-bit Sigma Delta Analog-to-Digital Converter (ADC) with a low-noise programmable gain amplifier and a fully differential high impedance analog input multiplexer. A true continuous background calibration feature allows calibration at all gains and output data rates without interrupting the signal path. The background calibration feature essentially eliminates gain and offset errors across temperature and time, providing measurement accuracy without sacrificing speed and power consumption.
Another feature of the LMP90080-Q1 is continuous background sensor diagnostics, allowing the detection of open and short circuit conditions and out-of-range signals, without requiring user intervention, resulting in enhanced system reliability.
Two sets of independent external reference voltage pins allow multiple ratiometric measurements. In addition, two matched programmable current sources are available in the LMP90080-Q1 to excite external sensors such as resistive temperature detectors and bridge sensors. Furthermore, seven GPIO pins are provided for interfacing to external LEDs and switches to simplify control across an isolation barrier.
Collectively, these features make the LMP90080-Q1 a complete analog front-end for low-power, precision sensor applications such as temperature, pressure, strain gauge, and industrial process control. The LMP90080-Q1 is ensured over the extended temperature range of -40°C to +150°C and is available in a 28-pin package with an exposed pad.
|Sample Rate (Max) (kSPS)|
|Number of input channels|
|Operating temperature range (C)|
|Approx. price (US$)|
|Power consumption (Typ) (mW)|
|Package size: mm2:W x L (PKG)|
|Input range (Max) (V)|
|Input range (Min) (V)|
|Analog voltage AVDD (Min) (V)|
|Analog voltage AVDD (Max) (V)|
|Digital supply (Min) (V)|
|Digital supply (Max) (V)|
|INL (Max) (+/-LSB)|
|-40 to 150|
|HTSSOP | 28|
|4.96 | 1ku|
|28HTSSOP: 62 mm2: 6.4 x 9.7 (HTSSOP | 28)|
Excitation Current Sources (iDACs)