Cabin & HVAC temperature sensing

Cabin, ambient and HVAC evaporator temperature points typically use small sensors placed close to the air flow or surface being monitored. Designers choose between NTC plus an ADC front end or digital temperature ICs on I²C or SENT, depending on harness length and ECU pin budget. Key filters are range, accuracy class, response time and the package that best fits ducts or housings.

Local board temperature & diagnostics

Body ECUs often include one or more sensors to supervise PCB and power-stage temperature. Here the goal is to track long-term stress and protect MOSFETs, regulators or RF sections, so moderate accuracy and slower response are acceptable. Common choices are digital temperature sensors near hot spots or NTC networks connected to spare ADC channels, selected by supply range, interface and warning thresholds.

Integrated temperature channels in other sensors

Many pressure, IMU and TPMS sensor ICs embed an auxiliary temperature channel used for internal compensation and external reporting. This can remove the need for a separate device when the sensor already sits at the critical location. Selection then focuses on whether the built-in channel covers the required range and accuracy, and how easily the ECU can read it over the chosen digital interface.

Body pressure sensors and media overview

Body-related pressure sensors monitor low-pressure air paths, mid-range refrigerant and coolant loops and higher pressure hydraulic lines. Many applications can use integrated modules with built-in signal conditioning, exposing an analog ratiometric or digital output to the ECU. Selection typically balances media compatibility, low / medium / higher-pressure ranges and package options that suit manifolds, pipes or tank housings.

Tyre pressure sensing and TPMS-oriented SoCs

Tyre pressure monitoring modules combine a low-leakage MEMS pressure element with an auxiliary temperature sensor, a low-power MCU and an RF front end inside a sealed wheel unit. The pressure IC must tolerate cycling over typical inflation and overpressure ranges and remain accurate across the full ambient spectrum. From the body ECU point of view, tyre pressure appears as decoded RF packets, while details of power management and wireless protocols belong to the dedicated TPMS function.

Brake and hydraulic pressure for safety functions

Brake and hydraulic pressure monitoring calls for sensors aimed at higher-pressure ranges and stronger diagnostics than comfort-only functions. Devices are often packaged in metal housings with threaded ports and automotive connectors, feeding analog or SENT outputs into ABS / ESC controllers for fast, redundant readings. Here, the main filters are media rating, mounting style and safety integrity, while control loops and redundancy schemes are handled on the brake control side.

Crash and airbag accelerometers

Airbag systems rely on accelerometers that can resolve crash pulses quickly and reliably over low-g ranges matched to vehicle deceleration profiles. Devices may sit inside the airbag ECU or at remote points on the body structure and typically include self-test features and defined fail-safe behaviours. They are designed for the highest safety integrity levels in the vehicle, with output formats and mounting driven by the crash algorithm requirements rather than comfort sensing.

Ride comfort and body motion sensing

Active suspension and damping systems use accelerometers tuned for body and wheel motion rather than crash pulses. These sensors sit on the chassis, suspension towers or in comfort ECUs and operate over medium acceleration ranges and bandwidths, with emphasis on noise, stability and matching across axes. Outputs are usually digital, such as SPI or I²C, feeding a suspension or body controller that blends motion information with wheel-speed and valve actuation data.

Vehicle- and cabin-level IMUs

Multi-axis IMUs combine accelerometers and gyroscopes, and sometimes magnetometers, to give a full picture of vehicle attitude and motion. A body-focused IMU may sit close to the vehicle centre of gravity or inside a domain controller that also receives steering, wheel-speed and GNSS data. IMU selection revolves around bias stability, noise and temperature drift, while the actual fusion algorithms and navigation functions belong to wider INS and ADAS compute pages.

Position and angle sensing for EPS, pedals and seats

Angle and position sensors use magneto or Hall front ends to track steering torque and angle, pedal position and seat or rail travel. Many devices support absolute or incremental encoding and offer sine / cosine outputs, PWM or SENT interfaces to match powertrain or body controllers. Selection usually weighs range of motion, required absolute accuracy, interface type and whether richer diagnostics are needed for safety-related EPS or pedal paths.

Speed sensing for wheels and rotating machines

Wheel-speed and motor-position sensing often uses differential Hall or magneto interfaces looking at toothed wheels or magnets on the shaft. These sensors deliver digital pulses or SENT / PWM signals that encode direction, speed and sometimes index information for commutation. Device choice focuses on operating air gap, low-speed performance, high-speed robustness and diagnostic capabilities when feeding ABS / ESC, EPS or inverter controllers.

Simple on / off switches for doors, latches and covers

Many body functions only need a robust on / off indication, such as door, hood and trunk open status, latch positions or seat-back locks. Here, latch-type or unipolar Hall switches replace mechanical contacts and provide a clean digital output into the BCM or dedicated body module. Diagnostics are typically basic, with emphasis on mechanical robustness, package style and tolerance of manufacturing variation rather than high-precision encoding.

Short-range ToF for doors and tailgates

Exterior ToF sensors support hands-free tailgate opening, door kick detection and short-range presence sensing near the body shell. The IC typically integrates a laser driver, SPAD or similar array and a timing front end, exposing distance or thresholded proximity over a digital interface. Selection centres on range class, field of view and how reliably the optical path works behind trim, bumper or handle plastics over the vehicle lifetime.

Interior ToF sensors for gesture and presence

Inside the cabin, ToF devices can detect hand gestures near the HMI, confirm occupant presence or refine safety zones around controls. These applications often trade long range for finer near-field resolution and tighter integration with display or infotainment modules. The ToF sensor typically feeds a local processor that interprets gesture or presence states before passing compact events into the main infotainment or body ECU.

Optical integration and contamination robustness

Successful ToF deployments depend heavily on mechanical and optical integration. Designers must consider the cover window material, angle and thickness, as well as how water, dirt and ice affect returns. Many sensor ICs offer configurable thresholds and built-in diagnostics to flag blocked or degraded optical paths. These traits, along with connector placement and harness routing, often matter as much as the raw distance specification.

Temperature sensors

• Placement: cabin, duct, evaporator, PCB hotspot or integrated inside another sensor IC.
• Response time class: slow, moderate or fast behaviour depending on whether you are tracking comfort, protection or transient events.
• Standalone vs integrated: clarify if you expect a discrete temperature sensor or can reuse a temperature channel in a pressure, IMU or TPMS device.

Pressure sensors

• Media type: air, brake fluid, refrigerant, fuel / DEF, coolant or another specified fluid.
• Overpressure margin: the qualitative level of overpressure and burst strength required by the system, for example comfort-level vs hydraulic brake requirements.
• Port and mounting style: manifold mount, threaded metal port, hose barb or custom housing expectations.

Acceleration & IMU sensors

• Axes count: single-axis, dual-axis, 3-axis accelerometer or multi-axis IMU such as 6-axis or 9-axis.
• Bandwidth class: crash pulses, ride and vibration or low-frequency attitude and stability sensing.
• Noise and stability class: comfort-level noise versus stability- or navigation-grade performance expectations.

Hall & magneto sensors

• Range and travel: approximate mechanical travel or angle range and whether you need end-stop coverage.
• Linear vs switch: continuous position output versus simple on / off threshold behaviour.
• Angle vs speed role: angle encoder for steering or pedals versus speed and direction sensing on wheels or rotors.

ToF & optical distance sensors

• Range class: very short, short or medium range depending on whether the sensor is used for kick detection, door proximity or interior interaction.
• Field of view: narrow, medium or wide coverage relative to the mounting point and target area.
• Target reflectivity class: expectations for dark clothing, low-reflectivity surfaces or highly reflective trim around the sensing zone.

Temperature sensors for cabin, HVAC and comfort

Most major vendors offer automotive-qualified temperature sensing that can be used in cabin, ambient, duct and seat applications. Some provide standalone analog and digital temperature sensor families, while others integrate temperature channels into pressure, IMU or TPMS devices used in the body domain.

• TI, ST and NXP publish broad automotive temperature sensor portfolios for HVAC, powertrain and body modules.
• Renesas and onsemi often embed temperature sensing into body-domain controllers, pressure sensors and mixed-signal ICs.
• Microchip and Melexis provide standalone automotive temperature sensors and devices with integrated temperature channels.

Pressure sensors for TPMS, HVAC and hydraulic systems

Pressure sensing in the body domain appears in TPMS modules, HVAC refrigerant monitoring and, in some platforms, hydraulic or brake-related sensing. Vendors offer families that target tyre-inflation ranges, refrigerant lines and fluid or manifold pressures with automotive qualification.

• Melexis, onsemi and NXP offer automotive pressure sensor families widely used in TPMS and body modules.
• TI, ST and Renesas provide pressure sensing solutions that span HVAC, fuel and hydraulic applications.
• Microchip contributes pressure and sensor-interface ICs that can serve body and chassis functions.

Acceleration & IMU sensors for crash and ride

Acceleration and IMU devices in body applications tend to support airbag crash detection, ride and comfort control and some stability or pose sensing. Several vendors offer crash accelerometers and automotive IMU families that can sit either in the airbag ECU or on the body and chassis side.

• ST, NXP and Bosch-affiliated suppliers are common sources of automotive IMUs and crash accelerometers used in body and safety systems.
• TI, Renesas and onsemi complement this with sensor interfaces and selected accelerometer options for ride and comfort.
• Melexis and Microchip participate where integrated sensing fits specific body modules or safety functions.

Magneto & Hall sensors for position, speed and switches

Magneto and Hall devices are heavily used for door and latch switches, seat and pedal position sensing, steering torque and angle measurement and wheel-speed or rotor sensing. Vendors typically maintain families of Hall switches, latches, linear and angle sensors and speed sensors aimed at automotive body and chassis functions.

• Melexis and onsemi are well known for broad automotive Hall and magneto sensor portfolios for body and powertrain.
• NXP, TI and ST provide families for position and angle sensing, wheel-speed and simple on / off switches.
• Renesas and Microchip add Hall and position sensing into selected body, motor and actuator platforms.

ToF & optical distance sensors for proximity and gesture

Time-of-flight and optical distance sensing in the body domain covers kick sensors under tailgates, door and handle proximity and interior gesture and presence detection. Here, vendors either offer standalone ToF ICs or integrate ToF and optical sensing into broader interior-monitoring and HMI solutions.

• ST, onsemi and other imaging-focused vendors publicise automotive ToF and proximity sensor families for exterior and interior use.
• TI, NXP and Renesas provide sensor interfaces and reference designs that host ToF and optical sensors in body modules.
• Melexis and Microchip appear where ToF or optical sensing complements existing body and comfort sensing portfolios.