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1: Preliminary Concepts
https://phys.libretexts.org/Courses/Berea_College/Electromagnetics_I/01%3A_Preliminary_Concepts
In electromagnetics, the electric field intensity ${\bf E}$ is a real-valued vector field that may vary as a function of position and time, and so might be indicated as “ ${\bf E}(x,y,z,t)$ ,” “\({\...In electromagnetics, the electric field intensity ${\bf E}$ is a real-valued vector field that may vary as a function of position and time, and so might be indicated as “ ${\bf E}(x,y,z,t)$ ,” “ ${\bf E}({\bf r},t)$ ,” or simply “ ${\bf E}$ .” When expressed as a phasor, this quantity is complex-valued but exhibits no time dependence, so we might say instead “ $\widetilde{\bf E}({\bf r})$ ” or simply “ $\widetilde{\bf E}$ .” An example of a scalar field in electromagnetics is the electric pot…
1: Preliminary Concepts
https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_I_(Ellingson)/01%3A_Preliminary_Concepts
In electromagnetics, the electric field intensity ${\bf E}$ is a real-valued vector field that may vary as a function of position and time, and so might be indicated as “ ${\bf E}(x,y,z,t)$ ,” “\({\...In electromagnetics, the electric field intensity ${\bf E}$ is a real-valued vector field that may vary as a function of position and time, and so might be indicated as “ ${\bf E}(x,y,z,t)$ ,” “ ${\bf E}({\bf r},t)$ ,” or simply “ ${\bf E}$ .” When expressed as a phasor, this quantity is complex-valued but exhibits no time dependence, so we might say instead “ $\widetilde{\bf E}({\bf r})$ ” or simply “ $\widetilde{\bf E}$ .” An example of a scalar field in electromagnetics is the electric pot…

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