2. IoT: hoe werkt het?
• Aan de basis ligt eender welke elektronische
sensor;
• IoT sensoren zijn voorzien van een manier
om draadloos te communiceren;
3. IoT: hoe werkt het?
• Door deze draadloze
communicatie bereiken de
sensoren via diverse kanalen
het internet.
4. IoT: hoe werkt het?
• En via het internet worden de
toepassingen bereikt;
• Vaak loopt dit via een IoT platform;
• De combinatie van sensoren en
toepassingen maakt een quasi
onbeperkt aantal use cases mogelijk.
5. Use case: crowdscan (Imec)
• Measures the average signal attenuation of a wireless sensor network relative to the empty environment;
• Provides a privacy non-instrusive way of measuring crowds.
13. Use case: Quake Alert
• Uses sensors to detect the
nearly constant
tremors;
• Visually depicts a quake in
progress;
• Sends alerts to citizens’
smartphones to give them
time to take cover.
14. Use case: public
transport
• Snelheidssensoren;
• Herkennen verloren voorwerpen;
• Sensoren op motor;
• Opvolgen rijgedrag;
• Aantal passagiers tellen;
• Voorrang verschaffen aan bus;
• Informatie verstrekken over verwachte
aankomsttijd.
Use case:
Public transport
15. • Connected devices that allow
clinicians to monitor their
patient’s safety and well-being;
• Outdoor GPS tracking devices.
Use case: Dementia
(locatemotion)
16. • A belt-mounted wearable sensor automatically
recognizes unsafe biomechanics such as
bending, overreaching, and twisting;
• Workers receive continuous coaching with a
light vibration;
• Collected data provides management with
valuable analytics and actionable insights to
improve workplace ergonomics.
Use case:
Workplace Safety
(Kinetic)
19. Wireless vibration and
temperature sensors send
data to Nikola’s Vibration
Analysts multiple times
each day
Nikola’s Vibration Analysts
monitor asset data 24/7 for
patterns that could cause
assets to fail
As alerts occur Nikola’s
Vibration Analysts help
prescribe corrections or
integrate with your CMMS
Low maintenance: no
broken sensors, no batteries
to replace
Use case: preventive maintenance
23. Manage your office space
• Usage Pattern Analysis
Understand which areas have higher or lower employee density - Assess
day of week/ time of day and location-based work patterns;
• Safe Distancing
Manage density in workspaces and meeting rooms, re-route heavily used
pathways, and configure alerts that trigger when a space exceeds safe
occupancy;
• Better Workplace Sanitization
Use sensor data to optimize and validate cleaning routines. Identify areas
that may have been missed - Schedule high traffic and high-density areas
for deep cleaning;
• Smart Desk Hoteling
Sensors mounted underneath desks identify which workspaces are in use -
Connect to a desk reservation system for smart booking.
23
24. 24
Smart water detectors
Sends leak, temperature, and
humidity alerts
Works with Smart Water Shutoff
Use case:Protect
against water
(Flo technologies)
A passive infrared sensor (PIR sensor) is an electronic sensor that measures infrared (IR) light radiating from objects in its field of view. They are most often used in PIR-based motion detectors. PIR sensors are commonly used in security alarms and automatic lighting applications.
PIR sensors detect general movement, but do not give information on who or what moved. For that purpose, an imaging IR sensor is required.
PIR sensors are commonly called simply "PIR", or sometimes "PID", for "passive infrared detector". The term passive refers to the fact that PIR devices do not radiate energy for detection purposes. They work entirely by detecting infrared radiation (radiant heat) emitted by or reflected from objects