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Linear density

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From Wikipedia, the free encyclopedia

Measure of a quantity of any characteristic value per length

For other uses, seeDensity (disambiguation).

The linear density, represented by λ, indicates the amount of a quantity, indicated by m, per unit length along a single dimension.

Linear density is the measure of a quantity of any characteristic value per unit of length.Linear mass density (titer intextile engineering, the amount of mass per unit length) andlinear charge density (the amount ofelectric charge per unit length) are two common examples used in science and engineering.

The term linear density or linear mass density is most often used when describing the characteristics of one-dimensional objects, although linear density can also be used to describe the density of a three-dimensional quantity along one particular dimension. Just as density is most often used to mean mass density, the term linear density likewise often refers to linear mass density. However, this is only one example of a linear density, as any quantity can be measured in terms of its value along one dimension.

Linear mass density

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Consider a long, thin rod of mass $M {\displaystyle M}$ and length $L {\displaystyle L}$ . To calculate the average linear mass density, ${\bar {\lambda }}_{m}$ , of this one dimensional object, we can simply divide the total mass, $M {\displaystyle M}$ , by the total length, $L {\displaystyle L}$ : ${\bar {\lambda }}_{m}={\frac {M}{L}}$ If we describe the rod as having a varying mass (one that varies as afunction of position along the length of the rod, $l {\displaystyle l}$ ), we can write: $m=m(l)$ Eachinfinitesimal unit of mass, $d m {\displaystyle dm}$ , is equal to the product of its linear mass density, $\lambda _{m}$ , and the infinitesimal unit of length, $d l {\displaystyle dl}$ : $dm=\lambda _{m}dl$ The linear mass density can then be understood as thederivative of the mass function with respect to the one dimension of the rod (the position along its length, $l {\displaystyle l}$ ) $\lambda _{m}={\frac {dm}{dl}}$

TheSI unit of linear mass density is thekilogram permeter (kg/m).

Linear density offibers andyarns can be measured by many methods. The simplest one is to measure a length of material and weigh it. However, this requires a large sample and masks the variability of linear density along the thread, and is difficult to apply if the fibers are crimped or otherwise cannot lay flat relaxed. If the density of the material is known, the fibers are measured individually and have a simple shape, a more accurate method is direct imaging of the fiber with ascanning electron microscope to measure the diameter and calculation of the linear density. Finally, linear density is directly measured with avibroscope. The sample is tensioned between two hard points,mechanical vibration is induced and thefundamental frequency is measured.^[1]^[2]

Linear charge density

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Main article:Linear charge density

Consider a long, thinwire of charge $Q {\displaystyle Q}$ and length $L {\displaystyle L}$ . To calculate the average linear charge density, ${\bar {\lambda }}_{q}$ , of this one dimensional object, we can simply divide the total charge, $Q {\displaystyle Q}$ , by the total length, $L {\displaystyle L}$ : ${\bar {\lambda }}_{q}={\frac {Q}{L}}$ If we describe the wire as having a varying charge (one that varies as a function of position along the length of the wire, $l {\displaystyle l}$ ), we can write: $q=q(l)$ Each infinitesimal unit of charge, $d q {\displaystyle dq}$ , is equal to the product of its linear charge density, $\lambda _{q}$ , and the infinitesimal unit of length, $d l {\displaystyle dl}$ :^[3] $dq=\lambda _{q}dl$ The linear charge density can then be understood as the derivative of the charge function with respect to the one dimension of the wire (the position along its length, $l {\displaystyle l}$ ) $\lambda _{q}={\frac {dq}{dl}}$