Your Contact to Sensirion

Umschlag

Contact

Contact our sensor experts:

Contact Form

Distributoren

Distributors

Here you find the nearest distributor in your area:

Our Distributors

Standorte

Locations

Find out where we are located:

Our Locations

toggle menu
  • Home
  • News
  • Sensirion Products
    • SEK-SensorBridge (Evaluation Kit)
    • SEN5x Environmental Sensor Node
    • SCD4x CO2 Sensors
    • SFA30 Formaldehyde Sensor Module
    • SGP41 VOC+NOx Sensor
    • SGP40 VOC Sensor
    • SHT4x Humidity and Temperature Sensors
  • Partner Spotlight
    • Partner Spotlight SparkFun
    • Partner Spotlight MikroElektronika
    • Partner Spotlight Seeed
  • Archive
    • Platforms
      • Environmental Sensor Shield
      • Smart Gadget Development Kit
      • Wearable Development Kit
      • Raspberry Pi
      • Qualcomm Snapdragon
      • Arduino
      • Cypress PSoC Series
      • Generic Linux Support
      • Thingstream MQTT IoT Sensor Starter Kit
    • Applications
      • Sensors for Ventilation
      • CO2 Monitor Reference Design
      • SHTC3 BLE Beacon Development Kit
      • Directional Wind Meter Using SDP3x
      • Smart Speaker
      • Archive
    • Labs
      • #21 - Using an RJ45 Breakout Board Connect with Evaluation Kit Cables
      • #20 - Integrate Flex-PCB Sensors into Prototyping Setups
      • #19 - Smart Factory Particle Monitor Network
      • #18 - Inhalation Application Benefits
      • #17 - Sleep Analysis and Pulse Monitor
      • #16 - Thermal Comfort Sensor
      • #15 - Anti-Fogging for Bathroom Mirrors
      • #14 - Improved Puff Sensing of Inhalation Devices
      • #13 - Spirometer
      • #12 - Breath Detection
      • #11 - Stress, Mood and Emotion Sensing
      • #10 - CO2 Sensing in Car
      • #9 - Milk Fat Concentration Sensor
      • #8 - Presence Detection with IR Sensor
      • #7 - RH Sensor Trigger for BLE Beacon
      • #6 - Smart Inhaler
      • #5 - Windshield Ice Detector
      • >> See All Labs Ideas
    • Tutorials
      • Wearable Development Kit: Build Your Own Device
      • Wearable Development Kit: Logging Data
      • Raspberry Pi: SFM Software Package
      • Raspberry Pi: Alexa with Indoor Air Quality
      • Raspberry Pi: Using Flow Sensors
      • Raspberry Pi: Weather Station
      • Arduino: Create Your Own CO2 Monitor
      • Arduino: Stand-Alone Liquid Flow Meter
      • Arduino: Interface for Liquid Flow Sensors
      • Arduino: Weather Station
      • Arduino: Closed Loop Volume Controller Using Liquid Flow Sensors
      • Arduino: Interface for Multiple SF06 Liquid Flow Sensors
      • Arduino: Interface for SF06 Liquid Flow Sensors with Level Shifter
      • Arduino: CAN Bus Flow Meter
  • Global Website

Contact

search
cart
DOWNLOAD CENTER BUY NOW INVESTORS
Sensirion AG Switzerland
  • Home
  • News
  • Sensirion Products
    • SEK-SensorBridge (Evaluation Kit)
    • SEN5x Environmental Sensor Node
    • SCD4x CO2 Sensors
    • SFA30 Formaldehyde Sensor Module
    • SGP41 VOC+NOx Sensor
    • SGP40 VOC Sensor
    • SHT4x Humidity and Temperature Sensors
    • Sensirion Products

      Start testing our sensors

      Here you can find all information for evaluating and testing Sensirion's latest sensor solutions. From drivers and software to tutorials and quick start guides - we try to offer all tools necessary so that you can kick-start your application!

  • Partner Spotlight
    • Partner Spotlight SparkFun
    • Partner Spotlight MikroElektronika
    • Partner Spotlight Seeed
  • Archive
    • Platforms
      • Environmental Sensor Shield
      • Smart Gadget Development Kit
      • Wearable Development Kit
      • Raspberry Pi
      • Qualcomm Snapdragon
      • Arduino
      • Cypress PSoC Series
      • Generic Linux Support
      • Thingstream MQTT IoT Sensor Starter Kit
    • Applications
      • Sensors for Ventilation
      • CO2 Monitor Reference Design
      • SHTC3 BLE Beacon Development Kit
      • Directional Wind Meter Using SDP3x
      • Smart Speaker
      • Archive
        • On/Off Body Detection
        • Perspiration
        • Antifogging in VR Goggles
    • Labs
      • #21 - Using an RJ45 Breakout Board Connect with Evaluation Kit Cables
      • #20 - Integrate Flex-PCB Sensors into Prototyping Setups
      • #19 - Smart Factory Particle Monitor Network
      • #18 - Inhalation Application Benefits
      • #17 - Sleep Analysis and Pulse Monitor
      • #16 - Thermal Comfort Sensor
      • #15 - Anti-Fogging for Bathroom Mirrors
      • #14 - Improved Puff Sensing of Inhalation Devices
      • #13 - Spirometer
      • #12 - Breath Detection
      • #11 - Stress, Mood and Emotion Sensing
      • #10 - CO2 Sensing in Car
      • #9 - Milk Fat Concentration Sensor
      • #8 - Presence Detection with IR Sensor
      • #7 - RH Sensor Trigger for BLE Beacon
      • #6 - Smart Inhaler
      • #5 - Windshield Ice Detector
      • >> See All Labs Ideas
    • Tutorials
      • Wearable Development Kit: Build Your Own Device
      • Wearable Development Kit: Logging Data
      • Raspberry Pi: SFM Software Package
      • Raspberry Pi: Alexa with Indoor Air Quality
      • Raspberry Pi: Using Flow Sensors
      • Raspberry Pi: Weather Station
      • Arduino: Create Your Own CO2 Monitor
      • Arduino: Stand-Alone Liquid Flow Meter
      • Arduino: Interface for Liquid Flow Sensors
      • Arduino: Weather Station
      • Arduino: Closed Loop Volume Controller Using Liquid Flow Sensors
      • Arduino: Interface for Multiple SF06 Liquid Flow Sensors
      • Arduino: Interface for SF06 Liquid Flow Sensors with Level Shifter
      • Arduino: CAN Bus Flow Meter
Sensirion AG Switzerland
  •  

     

  • Sensirion Developers
  • Archive
  • Labs

Labs Idea #3: Intrusion / Open and Close Door Event Detection

Author: Sensirion Innovations Team - November 2017

  • Motivation
  • Approach
  • Implementation

Motivation

A surveillance camera will only detect intruders within its field of view. However, breaking into a house through a door or window will generate a pressure pulse, which can be detected with a sensitive pressure sensor. Also the opening and closing of doors generates an air pressure wave, which is reflected from the walls of the building. The frequency of reflection depends on the size of the resonating room. If the door is closed the room volume is smaller. Therefore, the resonance frequency of the reflected air wave is higher. If the door is opened the resonance frequency is lower due to adjacent rooms adding to the total room resonance volume.

A very sensitive air flow or pressure sensor can detect the air wave generated by breaking windows or the opening and closing of doors in a building. Thus, it is possible to detect an intrusion event happening somewhere in the building, even if the sensor is in a different room (as long as the pressure wave can travel freely within the house). It is also possible to distinguish between the opening and the closing of a door, if the air flow or pressure sensor resides within the room.

This valuable information can be used to drive actions for building control or surveillance purposes. A smart home might turn on lightning or a smart thermostat might increase or decrease temperature based on room occupancy and load.


Approach

Sensirion's flow sensor is a semiconductor MEMS version of the traditional hot wire anemometer. The sensing principle is based on thermal conductivity through the gas flowing over the sensor surface (figure 1).

Figure 1: Thermal measurement principle

In opposition to diaphragm based differential pressure sensors, Sensirion's CMOSens flow sensor characteristic shows high sensitivity especially at low air flows (figure 2). This allows to reliably measure ultra low flows and differential pressures.

Figure 2: Sensirion flow sensors are more sensitive at low differential pressures than diaphragm type pressure sensors

Sensirion's differential pressure sensors (SDP8xx or SDP3x) use the flow through principle explained in figure 1, but are calibrated for differential pressure output in Pascal (1 mbar = 100 Pa = 1 in. water column) instead of flow output. Whenever air flow is generated a pressure difference exists. Therefore, a differential pressure sensor can also detect air flow.

A Sensirion differential pressure sensor (SDP8xx or SDP3x) is capable of detecting pressure differences even below one Pascal. In order to detect the air wave from a breaking window or moving door, a set-up is required, which forces the air pressure wave to enter the differential pressure sensor through one port and leave the sensor through the other port. Therefore, the outgoing port of the differential pressure sensor needs to be isolated from the entry port. Otherwise the air pressure wave would enter the sensor through both ports and cancel out.

To isolate the outgoing port of the differential pressure from the entry port, the outgoing port was connected to a dead space (see figures 3-5).

Figure 3: One port of Sensirion's SDP8xx differential pressure sensor attached to a large dead volume
Figure 5: 3D printed small dead space enwraping one port of Sensirion's tiny SDP3x differential pressure sensor. The other SDP3x port is connected to the long cylindric port
Figure 4: Large dead volume (20 Liters). Sensor is attached to the left port of the dead volume

The event of an opening or closing door is also detected by its generated air turbulence (figure 6, 7).

Figure 6: Closing door and opening door quickly
Figure 7: Closing door and opening door slowly

The breaking of a window by an intruder is detected by the high preak of the generated air pressure wave (figure 8). For this measurement a SDP8xx was used with a tiny dead volume of one milliliter attached to the sensor's outgoing port (similar to the set-up in figure 5).

Figure 8: a breaking window generates a high pressure peak

The measurement results below demonstrate that Sensirion's SDP8xx and SDP3x differential pressure sensors can measure smallest air flows generated by a opening door (figure 9-10). While a large dead volume generates a higher differential pressure signal, even a small dead volume still allows to measure the resonance frequency of the air wave travelling through the room upon an open door event.

Figure 9: Opening door event generates a large signal (blue) measured with SDP8xx and one port attached to a 20 liter dead volume
Figure 10: Opening door event generates a small signal (red) still detectable with SDP3x and one port attached to a small 3 milliliter (= 3 cubic centimeters) dead volume

Depending on the resonance frequency of the reflected air waves in the room an «open door» event (larger room volume → lower frequency) could be distinguished from a «close door» event (smaller room volume → higher frequency).

A characteristic «open door» and a characteristic «close door» wavelet signal are convoluted with the measured air wave. If the air wave frequency matches the characteristic wavelet frequency a non zero output signal is generated in the time domain, allowing "real time" signal analysis and event classification (figure 11).

Figure 11: Signal analysis (convolution with a wavelet) of the air wave travelling through the room and reflecting back and forth from the walls allows to distinguish between open or close door events

Conclusion

  • Sensirion's differential pressure sensor can detect the burst of air generated by a breaking window
  • Closing and opening of doors is detectable
  • Good signal-to-noise even with very small dead volume

Implementation

This paragraph should give in a how to style how to build the solution for the own purposes.

To build an air movement detection sensor a Sensirion differential pressure sensor SDP8xx or SDP3x series (figure 12) can be sourced from distributors listed on the Sensirion website.

Figure 12: Sensirion SDP8xx and SDP3x series of differential pressure sensors

Communicate with the digital sensor over I2C according to the explanations in the SDP800 or SDP3x series data sheet or use the appropriate evaluation kit.


Patent Information

No information or recommendation presented on this website do absolve you from the obligation of investigating the possibility of infringement of third parties’ rights and, if necessary, clarifying the position.


Related Sensors to This Article

Sensirion Differential Pressure Sensors SDP3x

Differential Pressure Sensor SDP3x

The SDP3x differential pressure sensor measures just 5mm x 8mm x 5mm, opening up new dimensions of integration and applications possibilities. It features excellent accuracy and long-term stability.

Sensirion Differential Pressure Sensors SDP800, SDP810

Differential Pressure Sensors SDP800 Series

Differential pressure sensors of the SDP800 series are the reliable solution for precise air flow measurement in most demanding, but cost sensitive HVAC applications.


Follow Us

Sensirion Products

  • CO2 Sensors
  • Formaldehyde Sensors
  • VOC Sensors
  • Humidity and Temperature Sensors

Partner Spotlight

  • Sparkfun
  • MikroElektronika

Archive

  • Labs
  • Applications
  • Tutorials
  • Platforms

Further Information

  • Developer News
  • Download Center
  • FAQs
  • Contact
  • Locations

Your Contact to Sensirion

Umschlag

Contact

Contact our sensor experts:

Contact Form

Distributoren

Distributors

Here you find the nearest distributor in your area:

Our Distributors

Standorte

Locations

Find out where we are located:

Our Locations

Please Find Here Various Support Topics

Buy Our Products at Your Local Distributor

About Sensirion

Environmental Sensors

Flow Sensors

Media/Newsroom

Investors

Useful Links

Sensirion Automotive Solutions

Career

Support Center

Partner Access

General

Terms and Conditions

Terms and Conditions for US Customers

Supplier Social Responsibility

Quality, Environment and Ethics

Sensirion AG

Laubisruetistrasse 50

8712 Staefa ZH, Switzerland

Tel. +41 44 306 40 00

infosensirioncom

2022 © Sensirion AG Switzerland
  • Home
  • Sitemap
  • Privacy Policy and Cookies
  • Imprint
  • Login
  • Disclaimer