Overview
ABSTRACT
Radar was developed for the remote detection of targets and to replace visual detection. In practice, the most efficient absorbent materials strongly depend on parameters related to the particular situation (radar frequency, form of the emitted wave, bandwidth, form of the target, etc.). Their properties and requirements are therefore linked to many considerations, in particular absorption range, weight and geometries, power-handling, mechanical stability and manufacturing capabilities. This article presents the various types of narrow bandwidth screens, multilayer structures with very wide bandwidth, analogue screens and sequence selection screens. It also deals with the concepts of chiral screens and gives an example of an absorbent structure with a very wide bandwidth.
Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.
Read the articleAUTHOR
-
André de LUSTRAC: Professor at Paris Nanterre University - Center de Nanosciences et de Nanotechnologies Université Paris Sud, (Orsay, France)
INTRODUCTION
Radar absorbing materials (MAR) were developed in 1940, following the installation of the first radar networks. In English, they are often referred to as RAM (Radar Absorbing Materials).
The ideal MAR would resemble a paint that is effective for all polarizations over a wide frequency band and incidence range. Unfortunately, such a material does not exist, and the likelihood of one appearing in the near future is quite low.
In practice, the most effective type of absorber in a given situation is highly dependent on a number of parameters (radar frequency, shape of transmitted wave, bandwidth, target shape, etc.).
Absorbent requirements and properties are determined by the following considerations:
operating frequency: the absorber can be designed for single-frequency absorption or for multiple discrete frequencies, or for broadband applications;
wave incidence: the absorption of a material, especially if it is anisotropic, can be highly dependent on incidence;
composite or homogeneous medium: the absorbent is made up of a homogeneous material or a series of discrete or gradient media;
absorption range: a function of transmission losses through the absorbers ;
power handling: governed by the heat dissipation ranges of the absorbing materials and the breakdown voltages in any metallic patterns;
geometric considerations: thickness and surface area needed to achieve the required absorption levels;
Temporal stability: ageing of materials, taking into account physical and thermal degeneration due to continuous exposure to electromagnetic radiation;
ease of manufacture: ease of manufacturing, moulding or forming an absorbent on a given template;
Weight considerations: as low a weight as possible for airborne and aeronautical applications (3 to 4 kg/m 2 is a maximum value) or high weight ;
product production, sales and installation costs as low as possible; for example, Boeing's large anechoic chamber in Seattle, which can measure an entire Boeing 747, has a cost excluding electronics of over €20 million (in 2009).
The aim of this article is to enable readers to acquire or refine their knowledge of absorbent materials.
We'll be looking at :
the various types of broadband flat screens ;
resonant structures ;
...
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference
KEYWORDS
radar | radiofrequency waves | metamaterial | metasurface | absorbing materials | frequencies
CAN BE ALSO FOUND IN:
Home Materials Functional materials - Bio-based materials Composite materials in electromagnetism - Radar absorbant materials
Home Materials Plastics and composites Composite materials in electromagnetism - Radar absorbant materials
Home Electronic-photonic Radar technologies and their applications Composite materials in electromagnetism - Radar absorbant materials
This article is included in
Electronics
This offer includes:
Knowledge Base
Updated and enriched with articles validated by our scientific committees
Services
A set of exclusive tools to complement the resources
Practical Path
Operational and didactic, to guarantee the acquisition of transversal skills
Doc & Quiz
Interactive articles with quizzes, for constructive reading
Composite materials for electromagnetism
Bibliography
- (1) - - Article Wikipedia Radar.
- (2) - - Doc UIT, http://www.itu.int/rec/R-REC-P.676/fr
- (3) - CURRIE...
Software tools
There are several software tools available for solving Maxwell's equations and calculating the properties of absorbent materials, either general numerical calculation software (Matlab, Scilab, Octave, etc.), or more specialized software (Ansys, Comsol, CST, Quickfield, etc.).
Some are chargeable, others are available free of charge.
-
Paid tools: some of these products...
Websites
-
GRACE – American industrial and chemical conglomerate
-
HYPER-RF – The portal for microwave radio frequencies and communication technologies
-
KOCKUMS – Swedish...
Events
-
Conference Meta – Conférences internationales sur les métamatériaux
-
Conference Metamaterials2018 – Annual international conference on engineered materials and their applications
...
Directory
Manufacturers – Suppliers – Distributors (non-exhaustive list)
For information on electromagnetic composite materials and metamaterials, please consult the following manufacturers' websites:
-
SIEPEL – Specialist in the manufacture of electromagnetic absorbers
-
...
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference