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Radian per second

The radian per second (symbol: rad/s) is the coherent of and , measuring the rate at which an object rotates or oscillates around a or , equivalent to one of per second. Since the is a dimensionless unit defined as the ratio of to on a circle, the radian per second effectively has the dimensions of inverse time (s⁻¹), though it is conventionally expressed as rad/s to specify angular measure. This unit is fundamental in physics and for describing rotational motion, such as in , , and control systems, where it quantifies phenomena like the of , planetary orbits, or . In practical applications, ω in rad/s relates to v by the equation v = rω, where r is the , highlighting its role in converting between rotational and translational dynamics. Common conversions include 1 rad/s ≈ 9.5493 (rpm), facilitating use in contexts like machinery design. The unit also applies to in periodic motions, such as simple harmonic oscillators, where it denotes cycles per unit time in radians rather than hertz (which uses cycles per second).

Definition and Fundamentals

Angular Velocity Concept

Angular velocity is defined as the rate of change of , or , with respect to time. This describes how quickly an object rotates around a fixed or point, quantifying rotational motion in terms of angular progression rather than straight-line displacement. Mathematically, \omega is expressed as the derivative of \theta with respect to time t: \omega = \frac{d\theta}{dt} where \theta is measured in radians. This formulation captures the instantaneous rotational speed at any moment, analogous to linear in translational motion but applied to circular or curvilinear paths. Unlike linear , which has dimensions of per time and varies with distance from the center in rotational systems, is uniform for all points on a rotating about a fixed . The tangential linear v at any radius r from the is given by v = r \omega, linking the two concepts while highlighting 's role in describing the overall . Radians serve as the dimensionless unit for \theta, defined as the ratio of to radius, ensuring 's dimensional consistency in physical equations. The concept of originated in during the late , notably in Isaac Newton's (1687), where it underpinned analyses of planetary motion and rotational dynamics.

Unit Definition and Notation

The per second, denoted as rad/s or rad⋅s⁻¹, is the coherent derived unit of in the (). It quantifies the rate at which an object rotates, specifically corresponding to an of one over a time interval of one second. The radian itself, rad, is the coherent unit for plane angle, defined as the angle subtended at the center of a by an whose equals the of the circle. As a of two lengths ( to ), the radian is dimensionless, with special name and symbol retained for clarity in expressions involving . Consequently, the dimensional formula for \omega is [\omega] = \mathrm{T}^{-1}, reflecting its dependence solely on the inverse of time. To provide intuition on its scale, 1 rad/s equates to approximately 57.3 per second, given that 1 \approx 57.3^\circ (precisely $180/\pi degrees). Similarly, it corresponds to about 9.55 , since one revolution encompasses $2\pi radians.

Relations to Other Units

Conversions with Degree-Based Units

The conversion between radians per second (rad/s) and degrees per second (°/s) stems directly from the established relation that π radians equals 180 degrees, which defines the scaling factor for angular measures. This implies that to convert an angular from radians to degrees, one multiplies by 180/π, and the same factor applies to rates. Thus, the precise conversion is 1 rad/s = (180/π) °/s, which approximates to 57.2958 °/s. Conversely, 1 °/s = (π/180) rad/s, approximately 0.017453 rad/s. In practice, these factors are applied by multiplying the value in one unit by the appropriate constant to obtain the equivalent in the other. For instance, an angular velocity of 2 rad/s converts to 2 × (180/π) ≈ 114.5916 °/s. The derivation ensures consistency across scalar multiplications, preserving the physical meaning of rotational rate. A common application involves converting revolutions per minute (RPM), often used in engineering for engine speeds, to rad/s via intermediate degree-based units. Start by converting RPM to degrees per second: since 1 revolution equals 360 degrees and there are 60 seconds in a minute, 1 RPM = 360°/60 s = 6 °/s. For 60 RPM, this yields 60 × 6 = 360 °/s. Then apply the rad/s conversion: 360 × (π/180) = 2π rad/s ≈ 6.2832 rad/s. This step-by-step process highlights the intermediary role of degrees in bridging rotational counts to SI-consistent angular velocities. Care must be taken to distinguish angular velocity, which is a vector quantity incorporating direction (often along the axis of rotation via the ), from angular speed, its scalar magnitude. Conversions like those above apply directly to the magnitude but do not alter the directional component; confusing the two can lead to errors in vector-based analyses, such as torque calculations in .

Connections to Frequency Units

The radian per second (rad/s) serves as the unit for , which is mathematically linked to the ordinary measured in hertz (Hz) by the relation \omega = 2\pi f, where \omega denotes in rad/s and f represents in cycles per second. This connection arises because one complete corresponds to an angular displacement of $2\pi radians, making a scaled version of linear by the factor $2\pi. Consequently, an of 1 rad/s equates to a of \frac{1}{2\pi} Hz, or approximately 0.15915 Hz. In the context of sinusoidal motion, angular velocity represents the instantaneous rate of change of angular position, which varies throughout the . However, the average angular velocity over one full equals $2\pi f, reflecting the total angular sweep of $2\pi radians divided by the period T = \frac{1}{f}. This average provides a direct bridge to , enabling the characterization of periodic phenomena where the motion repeats identically after each . A key application of this relationship appears in representations, where the method models sinusoidal waves as the projection of a rotating onto a fixed . The angular speed of this rotating vector is precisely the \omega in rad/s, with the vector completing one full per at a rate tied to f Hz. Fundamentally, rad/s quantifies a continuous rate of angular progression, independent of cycle boundaries, whereas Hz counts discrete, full cycles per unit time, highlighting their complementary roles in describing rotational and oscillatory behaviors.

Role in the SI System

Coherence with SI Base Units

The (rad/s) is the coherent derived unit of in the (SI), formed by combining the radian—a dimensionless derived unit for plane angle—with the SI base unit of time, the second (s), yielding a dimension of s⁻¹. This status positions rad/s as an integral part of the SI's framework of derived units, where it expresses the rate of change of angular position without introducing extraneous factors. The radian itself traces its origins to 1873, when the term first appeared in print in examination questions set by James Thomson at Queen's College, Belfast, establishing it as a natural measure of based on the ratio of to radius. The , including the as a supplementary unit, was formally adopted in 1960 by the 11th General Conference on Weights and Measures (CGPM), marking the system's international standardization with seven base units and provisions for supplementary units like the radian to support angular measures. In 1995, the 20th CGPM eliminated the supplementary category, reclassifying the as a dimensionless derived unit to enhance coherence, a change that directly applies to units like rad/s. The 2019 SI redefinition, effective May 20, 2019, fixed the second's definition via the exact value of the caesium-133 hyperfine frequency (9 192 631 770 Hz), but preserved the unchanged size and coherence of derived units such as rad/s. Coherence in the SI requires that derived units, including rad/s, allow physical equations to retain their exact numerical form without conversion factors other than unity when expressing quantities in SI terms. For instance, in rotational kinematics, the equation relating angular velocity (ω in rad/s), angular acceleration (α in rad/s²), and time (t in s) is given by \omega = \alpha t with no additional numerical coefficients, ensuring seamless integration across SI equations for angular motion. The International Bureau of Weights and Measures (BIPM), established under the of 1875, coordinates the global maintenance of the through the CGPM and the International Committee for Weights and Measures (CIPM), including the definition and evolution of units like the and its derivatives to promote uniformity in scientific measurement. This role ensures that rad/s remains a standardized, coherent unit accessible worldwide for precise quantification.

Derived Nature and Dimensional Analysis

The radian per second (rad/s) is a derived unit for , with a dimensional expression of [θ]^{-1}, where [θ] represents the of plane angle and is the of time. Since the is defined as a in the system, [θ] = 1, causing the of rad/s to simplify to ^{-1}, the same as that of . This character of the stems from its geometric derivation: the plane angle θ in radians is the ratio of the s to the r of a , given by θ = s / r. Both s and r possess the dimension of [L], so θ has no (m/m = 1). Consequently, the s = r θ maintains dimensional balance, as the right side combines [L] with the θ to yield [L] on the left. The dimensional homogeneity of rad/s facilitates unit consistency in fundamental physical equations without requiring conversion factors. In Kepler's second law of planetary motion, the is (1/2) r2 ω, where ω in rad/s ensures the expression dimensions to [L]2-1 directly, mirroring linear momentum flux. Likewise, Euler's equations for rigid-body rotation, such as I α = τ - ω × (I ω), preserve dimensional integrity across terms when ω is in rad/s, as the involves only dimensionless angles. In contrast to non-coherent angular units like degrees per second, which necessitate multiplicative factors (e.g., π/180 for equivalence) to align with equations, rad/s inherently avoids such adjustments or auxiliary prefixes like "milli-" for small angles, as its dimensionless base aligns seamlessly with derived quantities. This coherence is evident in approximations such as sin θ ≈ θ for small θ, which hold without scaling when θ is in radians.

Applications in Physics and Engineering

Rotational Dynamics

In rotational dynamics, the radian per second serves as the standard unit for (ω), which describes the rate of change of angular position in the of rigid bodies. The fundamental relation governing the motion of rotating objects is Newton's second law for , expressed as \tau = I \alpha, where \tau is the net , I is the about the of , and \alpha is the defined as \alpha = \frac{d\omega}{dt} with units of rad/s². This equation parallels the linear form F = ma, highlighting as the rotational analog of and as that of linear . Angular velocity possesses a vectorial character, represented as a pseudovector \vec{\omega} directed along the axis of , with its magnitude equal to the scalar angular speed in rad/s; the direction follows the , where curling the fingers of the right hand in the direction of points the thumb along \vec{\omega}. This vector formulation is essential for analyzing three-dimensional and in systems like gyroscopes. The I quantifies the body's resistance to , depending on mass distribution relative to the rotation axis, and ensures that \omega remains dimensionally consistent in units. The rotational of a is given by K = \frac{1}{2} I \omega^2, where \omega in rad/s directly scales the energy quadratically, analogous to translational \frac{1}{2} m v^2. This expression derives from integrating the work done by over and underscores the energy implications of in systems like flywheels or planetary motion. For example, in a involving a with I subjected to constant \tau starting from rest, the builds as \omega = \frac{\tau t}{I}, obtained by integrating \alpha = \frac{\tau}{I} with respect to time; this yields \omega = 25 rad/s after 5 seconds for a wheel where I = 2 kg·m² and \tau = 10 N·m, illustrating practical acceleration in mechanical systems.

Oscillatory and Wave Phenomena

In oscillatory phenomena, the radian per second serves as the natural unit for , characterizing the rate of periodic in systems exhibiting (SHM). For a mass-spring system, the angular frequency \omega is given by \omega = \sqrt{k/[m](/page/M)}, where k is the spring constant and m is the of the oscillating object; this expression arises from the restoring F = -kx leading to the m \ddot{x} + kx = 0. Similarly, for a simple undergoing small-angle oscillations, \omega = \sqrt{g/l}, with g as the and l the of the ; this derives from the balance \tau = -m g l \sin\theta \approx -m g l \theta for small \theta, and using the I = m l^2, yielding the SHM equation \ddot{\theta} + (g/l)\theta = 0. In wave phenomena, the angular frequency \omega quantifies the temporal periodicity of wave propagation, related to the ordinary frequency f (in hertz) by \omega = 2\pi f. The phase velocity v of a wave is then expressed as v = \omega / k, where k = 2\pi / \lambda is the wave number and \lambda the wavelength; this relation holds for linear waves in media such as or electromagnetic waves, enabling the description of wave speed independent of for non-dispersive cases. A practical application appears in (AC) circuits, where for a series , the impedance Z is Z = \sqrt{R^2 + (\omega L - 1/(\omega C))^2}, with R as , L , and C ; here, \omega determines the reactive contributions from the and , influencing at \omega = 1/\sqrt{LC}. Phasor notation further illustrates the role of \omega in oscillatory and wave contexts, representing time-dependent quantities as complex exponentials e^{i\omega t} (or equivalently \cos(\omega t) + i \sin(\omega t)), where the real part corresponds to the physical ; this method simplifies analysis of superpositions and relationships in SHM, , and AC circuits by treating \omega as the scaling factor for temporal evolution.