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Provides an examination of the importance of barter in the radio industry based on a systematic random sample of 195 radio stations within the continental USA. Describes how data were collected to assess the prevalence of barter in the industry. Analyzes the managerial decisions pertaining to barter to provide basic understanding of barter programming and its role in the station manager’s strategic planning. Concludes that station managers are using barter more and more to reinforce their product offerings and reduce the squeeze on cash flow. Providing programming that hits the right people continues to be a challenge for station managers.

Personal digital assistants are making a comeback, thanks to industrial innovation.

Stranded on a desert island or in a hospital bed with only one book to read, the victim can do far worse than have a good dictionary on his favourite subject. You flick over the pages to look up something you want to know, your eye catches an adjacent entry which intrigues you and you are off on the fascinating game of being referred from one entry to another in your pursuit of knowledge. If the game is not to lead to frustration and anger the book must play fair by you, it must leave you with the feeling that you have really learnt something for your efforts, even if occasionally this is that the subject is too abstruse for concise treatment and you are fobbed off with a list of references.

The purpose of this paper is to provide a review of the industrial sensing applications of electromagnetic radiation (EMR) with an emphasis on wavelengths other than visible light. The paper is in two parts. This, the first, considers radiations with shorter wavelengths than visible light, i.e. γ radiation, X‐rays and ultra‐violet (UV).

The paper discusses the sensing applications of short wavelength EMR through reference to the techniques employed, products and their uses.

The paper shows that γ radiation, X‐rays and UV radiation are used in a wide range of industrial sensors for the measurement of physical variables, chemical compounds and gases. The phenomena employed include absorption, backscatter, photoionisation, fluorescence and reflection. Applications are extremely varied and embrace a diversity of industries.

The paper provides a detailed, technical review of the sensing uses of short wavelength EMR.

This paper aims to celebrate the 100th anniversary of Einstein's works, published in 1905.

The paper presents a brief appraisal of Einstein's work.

The paper reminds the reader of the 1905 discoveries, such as photoelectric phenomena, special theory of relativity and Brown's motions.

The paper deals with the problem of how Einstein's concept contradicts or follows the Faraday concept of electromagnetic fields.

This paper aims to focus on the most popular technique nowadays, the use of microwave irradiation in organic synthesis; in a few years, most chemists will use microwave energy to heat chemical reactions on a laboratory scale. Also, many scientists use microwave technology in the industry. They have turned to microwave synthesis as a frontline methodology for their projects. Microwave and microwave-assisted organic synthesis (MAOS) has emerged as a new “lead” in organic synthesis.

Using microwave radiation for synthesis and design of fluorescent dyes is of great interest, as it decreases the time required for synthesis and the synthesized dyes can be applied to industrial scale.

The technique offers many advantages, as it is simple, clean, fast, efficient and economical for the synthesis of a large number of organic compounds. These advantages encourage many chemists to switch from the traditional heating method to microwave-assisted chemistry.

This review highlights applications of microwave chemistry in organic synthesis for fluorescent dyes. Fluorescents are a fairly new and very heavily used class of organics. These materials have many applications, as a penetrant liquid for crack detection, synthetic resins, plastics, printing inks, non-destructive testing and sports ball dyeing.

The aim value of this review is to define the scope and limitation of microwave synthesis procedures for the synthesis of novel fluorescent dyes via a simple and economic way.

Describes how radio telemetry can interface with process control systems such as supervisory control and data acquisition [SCADA] and distributed control systems [DCS] greatly increasing their power and efficiency. Outlines the basis of radio telemetry, the behaviour of electromagnetic waves, frequency and wavelengths. Uses the water industry as an example of the use of a large scale and sophisticated SCADA system to provide date collection and control links over a large area. Concludes that the versatility of radio telemetry coupled with its cost‐effectiveness means that this technology can help to expand and improve communications in an increasing number of industries.

The nature of radiated radio frequency fields and the ways in which they may cause either beneficial or deleterious effects are reviewed. The uniqueness of this phenomenon in relation to the drafting of safety guides, and hence ultimately in relation to law, is pointed out. The existing strategy for the drafting of safety guides depends on the determination of “reasonable worst‐case” parameters for each of the mechanisms involved in the coupling process from source to potential hazard. The decisions on what constitutes a reasonable worse case are taken by an expert committee, but comparison of the resulting safety guides with the scant evidence of proven hazards suggests that the worst‐case view leads to a substantial overestimate of the actual hazards. It is suggested that this situation would be likely to be found to be extremely unsatisfactory if ever a hazard situation (whether proven, contended or hypothetical) were to be the result of litigation between belligerent parties. It is further suggested that substantial amelioration of this situation could result if a probabilistic view of the problem were taken. In this case the expert committee would decide on realistic probability density functions, rather than realistic worst‐case factors.

This study aims to model and investigate low-loss wave-propagation modes across random media. The objective is to achieve better channel properties for applying radio links through random vegetation (e.g. forest) using a beamforming approach. Thus, obtaining the link between the statistical parameters of the media and the channel properties.

A beamforming approach is used to obtain low-loss propagation across random media constructed of long cylinders, i.e. a simplified two dimensional (2D) model of agroforests. The statistical properties of the eigenmode radio wave propagation are studied following a Monte Carlo method. An error quantity is defined to represent the robustness of an eigenmode, and it is shown that it follows a known Lognormal statistical distribution, thereby providing a base for further statistical investigations.

In this study, it is shown that radio wave propagation eigenmodes exist based on a mathematical model. The algorithm presented can find such modes of propagation that are less affected by the statistical variation of the media than the regular beams used in radio wave communication techniques. It is illustrated that a sufficiently chosen eigenmode waveform is not significantly perturbed by the natural variation of the tree trunk diameters.

As a new approach to obtain low-loss propagation in random media at microwave frequencies, the presented mathematical model can calculate scattering-free wave-propagation eigenmodes. A robustness quantity is defined for a specific eigenmode, considering a 2D simplified statistical forest example. This new robustness quantity is useful for performing computationally low-cost optimization problems to find eigenmodes for more complex vegetation models.