Light sensors
Light-sensitive resistors, also known as photoresistors, respond to light by changing their resistance. In the dark, they are less conductive, but their conductivity increases when exposed to light. Ideal for light detection and control.- Kitronik Ambient Light Sensor Breakout Board Kitronik #5105 This circuit uses an SFH 320-3/4-Z phototransistor and provides an analogue signal which gives a representation of the levels of light that are falling on the phototransistor on the board. This is achieved by creating a potential divider using a 2M2 resistor and the phototransistor.Delivered in 5 to 30 days€ 4,05 Incl. VAT
- Whadda Twilight switch - WSL125 - construction kit Whadda #WSL125 The WSL125 is an educational soldering kit with a twilight switch that automatically controls your lighting based on the lighting conditions. Easy to assemble, adjustable sensitivity and works on 12VDC. Ideal for gardens, driveways and more.Delivered in 3 to 7 days€ 7,40 Incl. VAT
The 3 most popular Light sensors
What is a sensor?
A sensor can be considered an artificial sense organ in technology. With a sensor, a system perceives its environment or collects information that can be used to control actions. Most sensors are either electronic or mechanical, providing a fixed output based on a certain input.
What can you measure with a sensor?
Naturally, different sensors exist for various applications. Here's a brief list of quantities you can measure with sensors:
- Radiation
- Temperature
- Gases (such as humidity or CO2)
- Pressure
- Magnetism
- Level (such as water level in a tank)
- Movement
- Proximity
- Light/UV/infrared/colors
- Sound
- Distance
- Weight/force
- Orientation/direction
- Current
What should I look for when choosing a sensor?
Voltage
When choosing a sensor, it's important to know the voltage at which the sensor operates. Too high voltage will destroy the sensor, and too low voltage will make it work improperly or not at all. Mechanical sensors are less affected by this.
Output Type
All sensors have one or multiple outputs. An output sends a measurement value from a sensor. The nature of this signal depends on the type of the sensor's output.
- Digital output: A sensor with a digital output signals a logical value of 0 or 1. This means the signal is either present '1' or not '0'. There are thus two states. A digital output is very suitable for detecting the presence or absence of an object or for determining if a certain preset limit has been reached. Additionally, a digital signal can also convey numbers or entire registers through a defined communication protocol like I2C or SPI.
- Analog output: A sensor with an analog output provides a specific analog value (current, voltage, or resistance) based on the recorded input. For example, in measuring temperature, the output could display the value 27°C but also 50°C or 100°C. The advantage of analog output is that it can be directly connected to an actuator, like a sound sensor to an LED (VU meter). There are also ADC (analog to digital) converters available to make the analog signal digital.
- PNP Or NPN: Sensors with a PNP or NPN switching output have at least three connecting wires. The ‘+’ is the brown wire (pin 1), ‘-‘ is the blue wire (pin 3), and the switching wire is the black wire (pin 4). With a PNP switching output, the load is switched between the switching wire and the '-'. With an NPN switching output, the load is switched between the switching wire and the '+'.
- PushPull-switching output: This output is used when both NPN and PNP are required. A voltage above a certain value will cause NPN to switch, while a lower value will cause PNP to switch.
- Normally open/ normally closed: Furthermore, an output can be normally open (NO) or normally closed (NC). In a normally open output, the sensor will provide a '0' signal before switching and a '1' signal after switching. In a normally closed contact, this is reversed: a '1' signal before switching and a '0' signal after switching.
Measuring Range
It's important to know that a sensor has a certain measuring range. This range is clearly indicated for each sensor. If there's a range from 5mm – 250mm, the sensor can only measure within these distances. Any distance outside this range will either produce no output or an undefined one. These distances vary from sensor to sensor.
Resolution
By resolution, we mean "the smallest possible change a sensor can detect." For a positioning laser, this would be a shift or deviation in position. Often, higher resolution is associated with a more expensive sensor and/or slower reading time, so don't immediately opt for the highest available resolution.
How reliable is a sensor?
Generally, sensors are very reliable if you stay within their specifications. It's crucial to choose the right sensor for the application and consider its properties. A low-resolution sensor, for instance, will not be reliable for positioning objects on a PCB but will be reliable enough for less precise work, like avoiding obstacles with a robot.
How do you maintain a sensor?
Maintenance varies by sensor type. Mechanical sensors often require more maintenance than electronic sensors. Sometimes it's necessary to clean the sensor or replace components like lenses or filters. For sensors used in an industrial setting, regular inspection and calibration are recommended to ensure reliable operation.
How can I calibrate a sensor?
Calibration is crucial to ensure the accuracy of a sensor. The process depends on the type of sensor but generally involves comparing the sensor's output with a known standard value. Based on this comparison, adjustments are made as needed. Many sensors have built-in calibration procedures, but some require external equipment.
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