# Uniform Linear Motion: Velocity Source: algebrica.org - CC BY-NC 4.0 https://algebrica.org/velocity/ Fetched from algebrica.org post 14715; source modified 2026-03-20T22:29:55. ## Introduction Kinematics is the study of the motion of objects, describing their position, velocity, and [acceleration](../acceleration.md) over time. Before diving into a detailed explanation of these phenomena, it is essential to introduce some key concepts. - A material point is an idealized object whose size is considered negligible relative to the distances involved in its motion. - The trajectory is the path traced by a material point as it moves through space. - A motion is said to be rectilinear if its trajectory lies along a straight line. If a material point moves along a straight-line path at constant velocity, meaning that the distances traveled are proportional to the time intervals taken, the motion is called **uniform rectilinear motion.** ## Velocity Let’s consider two points, \\( x\_1 \\) and \\( x\_2 \\), representing the position \\( P \\) of a point at two successive moments in time, \\( t\_1 \\) and \\( t\_2 \\), respectively. ![](https://algebrica.org/wp-content/uploads/resources/images/velocity-1-1.png) We can express the following relationship: \\[ \\frac{x\_2 - x\_1}{t\_2 - t\_1} = v \\] This relationship shows that the distance traveled is proportional to the elapsed time, and the ratio remains constant, equal to the magnitude \\( v \\). The **instantaneous scalar speed** is defined as the limit of the ratio as the time [interval](../intervals.md) approaches zero: \\[ v\_s = \\lim\_{\\Delta t \\to 0} \\frac{\\Delta x}{\\Delta t} = \\lim\_{\\Delta t \\to 0} \\frac{x(t + \\Delta t) - x(t)}{\\Delta t} \\] where \\( v \\) represents the instantaneous speed, \\( \\Delta x \\) is the displacement, and \\( \\Delta t \\) is the time interval. Therefore, the instantaneous scalar speed is given by the [derivative](../derivatives.md) of \\(x = x(t)\\) with respect to time. * * * Let us now imagine that the position \\( P \\) of the point at time \\( t \\) is identified by the displacement [vector](../vectors.md) \\( \\vec{r} \\). The displacement from \\( P \\) to \\( P’ \\) occurs over a time interval \\( \\Delta t \\) and is represented by the vector \\( \\Delta \\vec{r} \\). We have: \\[ \\lim\_{\\Delta t \\to 0} \\frac{\\Delta \\mathbf{r}}{\\Delta t} = \\frac{d\\mathbf{r}}{dt} = \\mathbf{v} \\] ![](https://algebrica.org/wp-content/uploads/resources/images/velocity-2.png) Thus, we can define the **velocity vector** as: \\[ \\mathbf{v} = \\frac{dx}{dt} = \\mathbf{i} \\frac{dx(t)}{dt} \\] where \\(\\mathbf{i}\\) represents a directed and oriented vector. The velocity vector is tangent to the trajectory at each point, oriented according to the direction of motion, and has a magnitude equal to the scalar speed. - In uniform rectilinear motion, the velocity vector remains constant. - In uniform rectilinear motion, the trajectory’s position-time equation is a [straight line](../lines.md), meaning the position varies linearly with time. * * * Velocity is measured in units of length multiplied by time raised to the power of \\(-1\\), and its standard unit is meters per second \\((\\text{ms}^{-1})\\). ## Example Imagine a car traveling along a straight road at a constant speed of \\( v = 20\\ \\mathrm{m/s} \\). Since the velocity is constant, the distance traveled by the car is directly proportional to the elapsed time. The position \\( x(t) \\) of the car at any time \\( t \\) can be expressed as: \\[ x(t) = x\_0 + v t \\] where: - \\( x\_0 \\) is the initial position (at \\( t = 0 \\)). - \\( v \\) is the constant velocity. - \\( t \\) is the time elapsed. This means that for every second that passes, the car moves exactly 20 meters forward, without speeding up or slowing down. Let’s summarize the data in a table: \\[ \\begin{array}{c|c} \\text{Time } (\\mathrm{s}) & \\text{Position } (\\mathrm{m}) \\\\ \\hline 0 & 0 \\\\ 1 & 20 \\\\ 2 & 40 \\\\ 3 & 60 \\\\ 4 & 80 \\\\ \\vdots & \\vdots \\end{array} \\] ## Glossary - Kinematics: the study of the motion of objects, describing their position, velocity, and acceleration over time. - Material point: an idealized object whose size is considered negligible relative to the distances involved in its motion. - Trajectory: the path traced by a material point as it moves through space. - Rectilinear motion: motion whose trajectory lies along a straight line. - Uniform rectilinear motion: motion along a straight line with constant velocity, where distances traveled are proportional to time intervals. - Scalar speed: the limit of the ratio of displacement to time interval as the time interval approaches zero; the magnitude of the velocity vector. - Velocity vector: the rate of change of the displacement vector with respect to time; a vector tangent to the trajectory, oriented in the direction of motion, with a magnitude equal to the scalar speed. ## What is velocity - Velocity describes how fast and in what direction an object moves. - Scalar velocity refers to the absolute value of velocity, representing only the speed of the object without considering the direction. - Vector velocity is the rate of change of position with respect to time, expressed as a vector tangent to the trajectory and oriented in the direction of motion.