Measurement uncertainty is an important component of modern materials analysis: it indicates the boundaries within which the test results can be trusted. Such results are necessary for understanding of, for example, material and product tolerances and lifetimes, vital for plastic product reliability and safety. Determination of measurement uncertainty is normally quite laborious, but this book shows how the available interlaboratory test data for plastics can be used to calculate measurement uncertainty much more simply. It contains many interlaboratory test results in the fields of thermoanalysis, molar mass determination, and quantitative analysis of the composition of material, presented in tables and graphical charts, discussed in the text, and elaborated by practical examples. In addition to the evaluation by means of the presented data (top-down approach), the relationship to the bottom-up approach specified in the Guide to the Expression of Uncertainty in Measurement (GUM) is explained based on an example. Further sections deal with sampling, and the issue of whether or not the difference between analytical results is significant.

The use of smart materials in architecture is a dynamic and innovative area merging research, development, and use. Smart materials, with their reversible characteristics, respond to stimuli such as light, temperature, and electrical field by changing their form, color, viscosity, etc.

One of the most fascinating developments is the advent of Phase Change Materials. These materials make it possible, for example, to develop self-acting, kinetic facades and wallpaper that changes its color and pattern based on temperature and light.

The book presents the development of these materials and also describes their use in the contexts of architecture, design, and art. It offers a systematic overview with a detailed discussion of properties, technologies, products, and projects based on twenty groups of smart materials.

The use of smart materials in architecture is a dynamic and innovative area merging research, development, and use. Smart materials, with their reversible characteristics, respond to stimuli such as light, temperature, and electrical field by changing their form,color,viscosity, etc. One of the most fascinating developments is the advent of Phase Change Materials. These materials make it possible, for example, to develop self-acting, kinetic facades and wallpaper that changes its color and pattern based on temperature and light. The book presents the development of these materials and also describes their use in the contexts of architecture, design, and art. It offers a systematic overview with a detailed discussion of properties, technologies, products, and projects based on twenty groups of smart materials.