By Daniel Lehmann, R&D Engineer, Sensirion In a world where everything is getting smarter and more connected, the Internet of Things (IoT) is taking over. Due to increased demand in mobility and convenience, battery-powered devices are becoming more important, holding a key role in the IoT era. Many of these devices are sensors, and in particular environmental sensors, such as such as humidity and temperature sensors, which are integral to the IoT ecosystem. For engineers, development of IoT devices is becoming challenging; this involves gaining knowledge about connectivity and energy harvesting as well as sensor integration, and data processing and management. To take full advantage of the performance and features of environmental sensors, mechanical design rules must be considered. Unbeneficial housing and PCB designs may cause unexpected temperature and humidity deviations and could increase the sensors’ response time. Simply following four basic rules makes integration easy and straightforward. From our experience, we recommend mechanical integration of sensors as early as possible in a project, since the complexity of the integration will increase the later the housing is designed. Hence, the four basic rules to follow are: The sensor should be located as close to the environmental air as possible Most importantly, the sensor has to be exposed to the ambient as much as possible, and large openings in the housing should be used. This guarantees a fast system response and minimised influence of the housing. Furthermore, the sensor enclosure should be isolated from other parts of the device. This will reduce offsets of the integrated system. The sensor enclosure with a single aperture should be isolated from the other parts of the device The volume around the sensor, so-called “dead volume”, needs to be minimised, helping with the response time. The volume around the sensor, the so-called "dead volume", needs to be minimised Last but not least, the sensor should be placed in an area without heating sources like microcontrollers and, ideally, be thermally-decoupled, otherwise the heating effect of the other components will offset the sensor signal. If a mechanical solution is not sufficient to solve the issue, there are software-based compensation solutions. The sensor should be placed in an area without heating sources like MCUs and, ideally, be thermally-decoupled Humidity Response Time For proper humidity measurements it is important that the humidity at the sensor matches the one of the environment whilst acquiring data. Therefore, the sensor should be connected as close to environmental air as possible. Housing designs with a large dead volume and/or small aperture may act as a separation of the sensor and environment, which may result in highly increased response times. To achieve fast response times, consider the following guidelines: § Place the sensor as close to the environment as possible. § A design that allows airflow over the sensor is preferred to a design with a single aperture. § The dead volume should be as small as possible. § The aperture(s) should be as large as possible. § Filter membranes will slow down humidity response. Never use more than one membrane per aperture. § There should be no material inside the dead volume that can absorb humidity. Temperature Response Time Due to the thermal mass of a device, its temperature reacts slowly in response to environmental temperature changes. To achieve fast temperature response times, consider the following guidelines: § Thermal coupling of the sensor to the environment under test should be as strong as possible. § Thermal coupling of the sensor to the thermal mass of the housing (PCB) should be as weak as possible.