Product comparison RxD + LW2x20

Radar level sensor LW Radar distance sensor RxD Applications Level measurement Position determination Obstacle detection Distance measurement Opening angle 10° 8° with antenna 40° x 30° R1D100 140° x 50° R2D100 Hygiene approval LW2720 - Measuring range up to 15 m up to 50 m Housing material SS 316 L PA

Can the radar position sensor RxD also be used for level measurement?

In principle, the RxD can also be used to record fill levels, although country-specific characteristics must be taken into account. You can find an overview here . In general, the LW sensor is designed to record fill levels because it has a smaller opening angle and additional setting options such as an intelligent algorithm that allows installations to be hidden. This means faster commissioning can be achieved.

Radiated power in comparison

The following table provides an insight into the comparison of different transmitters and their radiated power. Transmitter Max. power [W] Radar sensor 0.1 WLAN 2.4 GHz 0.1 WLAN 6 GHz 0.2 DECT 0.25 WLAN 5 GHz 1 Mobile phone 2 LTE base station 40 5G base station 80 Radio and TV stations 500.000 Source: "Mobilfunk und Gesundheit, Deutsche Telekom Technik GmbH"

Is the use of radar sensors authorised at international level?

A radio approval is required to use a radar device. The radio standards differ from country to country, which is why we would like to point out that you should familiarise yourself with the country-specific laws before making a purchase.

Do radar sensors interfere with each other?

Radar sensors operate according the FMCW (frequency-modulated continuous wave radar) principle. This means that they radiate a continuous frequency-modulated signal. For two radar sensors to mutually interfere, they would have to undergo the same frequency modulation at the same time. However, this is very unlikely.

How do covers or obstacles affect the measurement?

Radar beams can see through some objects. These can be made of plastic and do not have to be completely transparent in order to allow radar beams to pass through. Thin covers made of plastics such as PFTE or acrylic glass have only a minimal effect on the measurement. Measurement deviations can occur with increasing thickness of the covers.

Why are power and RCS specified in dB?

In high-frequency technology, very large numerical values are used. The logarithm helps to better illustrate them. The conversion is as follows: G log [dB] = 10 · logG linear Linear Logarithmic 10 mW 10 dBm 20 mW 13 dBm 1000 mW 30 dBm

What is the difference between RCS and power?

Power is the energy reflected by an object, which decreases with increasing distance. The RCS value (radar cross-section) is an object-specific variable and a measure of how detectable an object is by radar. The RCS value, unlike the power, is independent of the distance and typically always the same (+/- 3dB). The radar cross-section depends upon a range of parameters, such as material, surface structure and object size.

Radar sensor technology and application areas

Find out more about the technology, operating principle and areas of application of radar sensors here.

Content

Radar technology at a glance
Properties and advantages
Influencing factors
Application areas
FAQ

Radar technology at a glance

Radar stands for Radio Detection and Ranging and is an important and innovative technology in automation technology that is used for numerous applications in both hygienic and industrial environments.
Radar sensors emit electromagnetic waves, whose frequency ranges stretch from approx. 30 MHz to approx. 300 GHz, with the echoes reflected by objects or media serving as active transmission and reception method to calculate their distance to the sensor.

ifm radar sensors utilise the Frequency Modulated Continuous Wave (FMCW) method. They emit high-frequency electromagnetic waves with a periodically changing frequency. These waves are reflected by objects, detected by the sensor’s receiving antenna and evaluated. Based on the time offset between the transmitted and reflected signal, information on distance, speed, direction and position can be precisely determined.

Properties and advantages of radar technology

Optimum performance even in demanding applications
Radar technology is resistant to harsh environments due to difficult weather and temperature-related conditions and extraneous light. Thus, the measurement remains accurate at all times.

Overcoming long distances
As radar waves propagate freely in air, objects or media can be detected over a long range. Depending on the type of application and sensor, the detection range can be up to 50 metres.

Penetrating different materials
The electromagnetic waves emitted by a radar sensor can penetrate a wide variety of materials. Plastic in particular allows the sensor to be covered or encased without affecting the measurement results.

Non-contact technology
Radar allows for objects and media to be detected even at great distances without direct contact. Even properties such as the medium’s density, viscosity, temperature and pH do not impact the measurement.

Fast and precise
The technology allows for fast, reliable and highly accurate measurements.

Factors influencing radar sensors

The radar cross-section

The radar cross-section (RCS) is a measure of how well an object is detectable by radar, i.e. how much of the emitted energy is reflected from the object. The higher the RCS value, the greater the reflectivity and therefore the visibility of the object.

The RCS value depends on factors such as material, medium, size and angle of incidence, but not on the distance of the reflection target as long as a reflection is not affected by the distance. The higher the dielectric constant and the bigger the object size and circumference, the better the visibility.

Radar frequency and antenna size

The radar frequency and the antenna size of the sensor are two key factors that determine the aperture angle and therefore the range and precision of a radar sensor.
A small aperture angle enables strong signal focussing, which has a positive effect on the range and precision of the sensor. Moreover, this enables for example interfering structures in tanks to be suppressed.
Good to know:

The smaller the antenna size, the larger the aperture angle at the same frequency.
The higher the frequency, the smaller the aperture angle for the same antenna size.
High frequencies enable compact designs due to the short wavelength.

Radar resolution

Radar resolution, also known as separability, describes a radar’s ability to clearly separate targets that are close to each other and output them as separate targets. In situations where targets differ only slightly in their measured values, there is a risk that they will merge into one target and not be detected individually.Basically, there are two types of radar resolution:

Distance resolution
The bandwidth of the transmission signal determines the distance resolution, which enables the radar sensor to differentiate between objects based on their difference in distance.
Objects that are positioned at similar lateral and elevation angles to the radar can still reliably be separated by the radar based on their distance from each other. However, the distance resolution alone is not sufficient for precise localisation.

Angular resolution
The angular resolution describes the radar’s ability to differentiate between objects based on the information at which angle these targets are located to the radar. Angular resolution can be divided into azimuth resolution (lateral angles) and elevation resolution (elevation angles).
The aperture angle (field of view) of the radar antenna is an important factor in terms of angular resolution. The angle determination performance is considerably influenced by the number and design of the antennas.

Radar sensor application areas

Position determinationConveyor monitoring
Vehicle positioning
Distance control and height measurement
Monitoring of surroundings and collision avoidance
Smart access control

Hygienic level measurementin storage tanks as high as 10 m
in mixing tanks with agitators
in CIP tanks with spray balls

Industrial level measurementin storage tanks as high as 10 m
in plastic tanks, e.g. IBC
outdoor use
flow rate measurement in Venturi flumes

Radar sensor technology and application areas

Radar technology at a glance

Properties and advantages of radar technology

Factors influencing radar sensors

The radar cross-section

Radar frequency and antenna size

Radar resolution

Radar sensor application areas

Position determination

Hygienic level measurement

Industrial level measurement

Radar sensor FAQs

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