Panasonic PIR Motion Sensor FAQ's

No, specific position detection of a person is not possible.

Panasonic passive infrared sensors have a QUAD sensing element, meaning only one sensor component with four pyroelectric, heat receiving elements which are all interconnected. The lens determines the size and shape of the detection area, as well as the distribution and number of the switching zones.

Therefore, because there is only one sensor component, it cannot identify where the infrared source is coming from within the detection area. On the other hand, if you use multiple Panasonic passive infrared sensors, it may be possible to identify the approximate position of a person.

No, there are not.

A regulator or other circuitry should be used to transform the voltage to 5V DC.

Yes, it is.

A design using parallel connections such as in the example below can be used.

It depends on certain conditions.

Therefore, it cannot be specified.

Detection occurs when the sensor generates an analog signal that extends beyond its threshold values. The slope of this analog signal can ramp drastically or minimally due to the detected change in temperature or movement speed of the object.

The output would be a repetition of ON/OFF.

When the detection state persists, the pyroelectric elements output an analog signal waveform continuously. The output analog signal is amplified by an amplifier circuit and when it exceeds the preset voltage level threshold, the sensor interprets this as motion by converting the signal to a digital ON output.
As the analog signal drops below the voltage threshold, the digital signal goes back to an OFF signal as the output.

It has become common practice to use the timer function of a microprocessor on the main board, so Panasonic infrared sensors do not implement it.
If you wish to see an example of a timer circuit, refer here.

The amount of infrared radiation emitted from the human body is very small and the signal cannot be processed by the circuit as is.

For this reason, the signal is amplified by an internal amplifier circuit. The amplified signal must be compared to a preset reference level.

If the amplified circuit is greater than the reference level, a person is considered to have entered the detection area and a digital ON signal is outputted.

The circuit that makes this comparison is called a comparator.

Modes:

Sleep Mode	When the output is OFF. The electrical current consumption during sleep mode is around 1μA.
Standby Mode	After the sensor’s output reaches ON status, the sensor switches to standby mode. The electrical current consumption gets close to 1.9μA. When the sensor’s output returns to its OFF value after the “hold time” expiration, " the sensor switches back to sleep mode.
Mask Mode	The time during which the output is forced to OFF after the end of the standby mode. (No detection is possible during this period.)

Durations:

t1(Twu)	Circuit Stability Time About 25s. (typ.)	During this stage, the output’s status is undefined (ON/OFF) and detection is therefore not guaranteed.
t2	Standby Hold Time About 2.6s (typ.)	The hold time can differ depending on the number of outputs happening during standby mode. (*1)
t3	Mask Time About 1.3s (typ.)	During this stage, even if the sensor detects something, the output will not switch to ON (*2)

A capacitor can be added as seen in the example below.

PaPIRs have a voltage output (Out) which can only drive a certain current. The digital sensors can drive a maximum of 100μA, whereas the analog sensors (EKMC26-series) can drive up to 200μA.

The user must consider & design the circuit connected to the voltage output so that the specified maximum output current is not exceeded.

Otherwise, the sensor shows unstable behavior and in the worst case can be damaged if this value is exceeded.

Panasonic infrared sensors do not work if more than 100μA is output.

There is a possibility of detection.

This sensor is specified to detect an object based on defined conditions.

The catalog is written as “Standard detection type 5m” and “Slight motion detection type 2m”, which is our “guaranteed detection distance”.

In reality, the detection cases may differ depending on the following factors.

• Temperature difference between target object and surroundings.
• Size of the target object and how it overlaps with the detection zones.
• Moving speed of the target object.

Therefore, there is the possibility that the sensor detects something beyond the specified “maximum distance”.

In addition, depending on the conditions, there is even the possibility that the sensor may not detect even within the specified detection distance.

Detection zone:
This is the area where people are detected. There are 4 heat receiving elements inside the sensor, and those elements are projected to the lens creating 4 detection zones per each facet of the lens.

Detection area:
The detection area is where the 4 detection zones are as one group. This is a set of detection zones projected by a single facet on the lens.

Detection range/distance:
If ceiling mounted - Detection range/distance is the installation height that the sensor will detect reliably as per specification.
If wall mounted - Detection range/distance that the sensor will detect reliably.

PaPIRs are able to function based on a temperature difference of 4°C between a heat source such as a person and the background such as a floor or wall.

The background is the environmental temperature such as the area around the ground, walls, and ceiling. When the person enters the detection range of the sensor, the temperature difference between the ambient temperature and object will be detected due to the sensing of change in infrared light.

Product life is estimated by an accelerated reliability test based on a THB (Temperature, Humidity, and Bias) test.

Using this evaluation method, we established that there is no problem storing the sensor indoors at normal temperatures and humidity for 5 years.

The quality guarantee period is one year.

No, it is impossible

The design concept requires that the target object be detected completely and passes through the detection zone.

The conditions are as follows:
• Size of the detection target.
• Movement speed of detection target.
• Temperature of the detection target. (temperature difference from surroundings)
• Distance between the target and the sensor

Yes, there is.

Sensitivity is inversely proportional to the size of the detection zone.
(The larger the detection zone, the more difficult it is to detect the object.)

The sensitivity is roughly inversely proportional to the square of the distance as defined by the Inverse Square Law.

The greater the distance, the larger the individual detection zones become. Larger detection zones reduce the sensitivity against small objects or small movements.

This amount indicates the incident energy intensity when the noise and signal output are equal.

The smaller this value is, the higher the detection capability which means that the noise level is reached with less light incident.

D* This is an index that component of the light receiving area is reflected in NEP.
It indicates the sensor detection performance as an actual product.

Panasonic has better detection performance even though the sensor has a smaller element compared to other solutions.

Element	PaPIRs	Company A	Company B	Company C
Size (mm)	0.6 x 0.6	2.6 x 0.7	1.0 x 1.0	1.0 x 1.0

 

Yes, detection is possible.

Panasonic Passive infrared sensors are able to detect movement through the interpretation of temperature differentials. A human body can be detected whether it is higher or lower than the ambient temperature. However, since the surface of the human body is affected by the ambient temperature to a certain extent, the sensitivity of the sensor may deteriorate if the body and ambient temperatures equalize.

Yes, detection is possible.

Pyroelectric sensors react to a change in intensity of infrared radiation within the specified detection criteria. All objects on earth emit infrared radiation and are therefore detected if they are moving and if the change in intensity is large enough to be detected (animals, insects, cleaning robots, curtains, flying objects, rain, etc.).

No, light is never emitted from the sensor.

PaPIRs are passive infrared sensors, which means that they do NOT emit infrared radiation to detect motion. Instead, the sensor operates by receiving infrared radiation emitted from a moving object. Therefore, it is called a “Passive type” sensor.

Yes, although the sensor itself can not adjust detection distance on its own due to the principle of its operation. In order to set the limitation of detection range, the sensor should be pointed toward an obstacle such as ground, wall, or ceiling.

It is also effective to limit the detection range by blocking the incoming infrared light by using a transmittance-reducing material in front of the lens like Polyethylene.

Another possibility would be to use the analog sensor with amplifier output. With this sensor, you can adjust the sensitivity to a certain degree by adjusting the switching thresholds within a software or with the help of a window comparator.

As indicated below, the sensor uses an optical filter with light transmission characteristics of approximately 5μm or longer.

It is defined as a long wavelength (far infrared) which is from approximately 5 - 15μm.

Pyroelectric elements are pyroelectric crystals provided with electrodes. With the help of an optical system, incident infrared radiation emitted by a moving person, for example, is focused on these pyroelectric elements by means of a lens, causing the crystals to change temperature. This temperature change leads to a charge shift at the electrodes. This charge shift generates a measurable voltage which is used to detect moving objects within the specified detection area.

PaPIRs are quad sensors, which means that four pyroelectric crystals are connected together on a carrier substrate. In contrast to sensors with one or only two pyroelectric elements, the probability of a triggering error is reduced with a quad sensor. False triggers can usually be caused by thermal interference sources in the environment, for example, by spontaneous shading of an object heated by the sun or quickly adjustable heat sources.

Only with certain precautions.

Panasonic passive infrared sensors are designed for indoor use with common indoor electronic devices.

If you need to use a sensor outdoors please take measures to waterproof the sensor and protect it from dust, condensation, and freezing.

There are many causes of temperature changes outdoors and because of that detection errors may result.

The sensor itself is not waterproof.

It is necessary to take water-proof measures by using O-rings or gaskets for example or HDPE suitable potting material (please contact potting material experts for HDPE suitable potting materials).

The high-density, long-distance, and low-profile lenses have a step for which O-rings or gasket seals can be placed (maybe CAD based pictures are a little bit more representative here).

Yes, you can, depending on the setting.

The detection area can be changed by changing the angle of the mounting of the sensor and by placing a cover with a slit or a mask in front of the sensor that limits the area detected by reducing the F.O.V. (Field of View).

If you find it difficult to calculate the desired detection area, please ask us. We can possibly create a field of view simulation upon request.

No, the sensor is not suitable for mounting on moving objects.

PaPlRs are normally installed in a stationary device. When an object enters the detection area, the sensor detects a change in the amount of infrared radiation in the detection area.

If the sensor were to move, it would mistake changes in wall and floor temperature for a moving object, which would incorrectly lead to detection. Strong shocks and vibrations can cause false alarms too, and in the worst case damage the sensor.

Yes.

Panasonic Passive infrared sensors detect when a human enters or exits the specified detection area.

However, if the person is too close to the sensor, the entire detection area is covered by the upper body, for example. As a result, temperature changes are less likely to occur with small movements in the detection area.

In addition, detection can be difficult if a person moves through the detection area at an extremely short distance, very quickly. In this case, the temperature change could be too fast for the sensor.

No, it cannot a person through these materials.

The wavelength which can be detected by this sensor is over 5μm.

Ordinary, light wavelengths passing through glass are limited to 2μm. Since the sensor can only detect infrared wavelengths greater than 5μm, glass would render the sensor unable to detect a person on the other side.

As an alternative, we suggest using a polyethylene sheet which allows for infrared light to pass through. However, if a sensor is placed opposite or close to a window, etc., it may react if the ambient temperature changes quickly enough, for example, if the sun is shaded by clouds, etc.

Yes, it does.

During summer, when the difference between the surface temperature of a human body and the background temperature is small, the sensitivity decreases. Conversely, during the winter, the sensitivity can increase depending on the amount of temperature differential between the object and the background ambient.

The detection performance does not change.

Yes, there is.

When sunlight suddenly illuminates or shades the sensor, a change in temperature occurs.

The sensor may detect this change, and there is a possibility to trigger a false detection.

Therefore, we recommend that the sensor should be installed in a place where it is not in direct sunlight.

Yes, it does.

Since Panasonic Passive infrared sensors detect the difference between the ambient temperature and the human body, the detection performance changes depending on the state of the target object and the ambient temperature.

Regarding the change due to clothes, this depends on how much skin is exposed. The human body emits more infrared light when more skin is exposed. The more energy radiated from the human body, the easier it is for the sensor to recognize infrared energy. Although people tend to cover up more with clothing during colder environments and winter seasons, the actual detection performance is actually still better in these climates. This is because the ambient temperature is lower in winter and the effect of lowering ambient temperature has a greater effect than the change of infrared emitted by the person due to clothing.

Generally, it is necessary to pay attention to changes in the ambient temperature more than the affects of clothing.

There is no true “Pet Immunity” type PIR sensor from Panasonic.

You can install the “wall installation detection” lens type upside down and tilt the lens so that the detection area does not cover near the ground.

However, this is only possible with smaller animals. Larger dogs for example could be detected. But also cats or dogs that move into the detection area trigger the sensor, for example when they jump or climb on an elevation (create a 3D CAD picture).

No, unless the airflow is blown directly across the lens or directly at the sensor. The principle of operation of the sensor is to detect changes in the amount of infrared energy.

Infrared energy = Temperature x Emissivity of the object

Therefore, because air is 0% emissivity, the sensor does not respond no matter how much the temperature changes.

However, when the airflow blows directly toward the sensor’s lens causing the temperature of the lens itself to change, there is the possibility of a false trigger. In addition, if the airflow changes the background temperature rapidly, the sensor may be sensitive enough to interpret this as warm body movement.

1. Below are the functional pin assignments:

Vdd power source (+)
GND power source (–)
Out output terminal

2. Connect the pins as follows:

Connect the (+) terminal of the power source to Vdd.
Connect the (–) terminal of the power source to GND.

3. Select an output resistor in accordance with Vout.

No, it cannot.

The circuit stabilization time is the time required for the internal circuit to stabilize after the power is turned on.

During this time accurate detection cannot take place as the output is unstable.

More than 1ms.

The pyroelectric elements’ output differs depending on the temperature difference between the object and its surroundings as well as the moving object’s speed. The output is amplified by an amplifier, and if the amplified output exceeds the reference voltage, the sensor interprets this as a detection by converting the analog signal to a digital ON output signal.

Although the output time is not always the same, the signal is more than 1ms due to the circuit characteristics.

It cannot be specified because it depends on too many parameters.

It may take some time to turn off depending on the conditions.

Yes, it can handle external surges to a certain extent. It depends on the quality of the power supply and the noise conditions of the surrounding environment such as noise amplitude, noise frequency and cable routing.

In principle, the sensor should be used in a low-noise environment.

Reference: The sensor is not affected by mobile phone noise with a minimum distance of 5 centimeters.

No, it cannot.

A mechanical relay or solid state relay should be connected to the output of the infrared sensor to turn the AC load on or off.

If a timer is needed, please refer here for an example of a timer circuit.

You can set the microprocessor’s timer function.

If the device does not have such a function, refer to the following circuit image below to create a timer as an example.