Standalone semiconductor sensors have rarely been considered for implementation into sensor probes or assemblies due to their larger geometries. However, advances in process technology and design have led to new, tiny sensor structures with almost linear transfer functions. In order to provide system designers with this new low-cost alternative to precision temperature measurement, this application report discusses the new LMT70 temperature sensor, whose footprint is less than 1 mm² , while its parametric performance challenges the accuracy of RTDs at cost levels lower than those of thermistors.

The serial peripheral interface (SPI) bus is an unbalanced or single-ended serial interface designed for short-distance communication between integrated circuits. Typically, a master device exchanges data with one or multiple slave devices. The data exchange is full-duplex and requires synchronization to an interface clock signal. However, recent trends in the design of industrial data-acquisition systems have not taken this synchronization requirement into account, and distances between the microcontroller and the corresponding analog-to-digital and digital-to-analog converters (ADCs and DACs) can reach 100 m or more.

The impact of the added propagation delay on the data-to-clock synchronicity is often ignored, and interface designs that operate perfectly in the lab environment cease operation when implemented on the factory floor. There can be multiple reasons for the interface malfunction. This article tries to shed light on the major ones, including:

• Lack of synchronization due to large propagation delays of the signal path
• Reduced noise immunity due to long-distance, unbalanced signal paths
• Damaged transceivers due to large ground-potential differences (GPDs)
• Data transmission errors due to unterminated data lines
• Transceiver latch-up and network downtime due to large electrical transients

In this application note we highlight the implications of ripple injection techniques, aimed at minimizing output ripple voltage, on the transient response of a supply. The results help choose a suitable ripple injection technique after striking a balance between the output ripple voltage and the transient response required by the load.