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Power, root-power, and field quantities
Power, root-power, and field quantities
Power, root-power, and field quantities
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A power quantity is a power or a quantity directly proportional to power, e.g., energy density, acoustic intensity, and luminous intensity.[1] Energy quantities may also be labelled as power quantities in this context.[2]

A root-power quantity is a quantity such as voltage, current, sound pressure, electric field strength, speed, or charge density, the square of which, in linear systems, is proportional to power.[3] The term root-power quantity refers to the square root that relates these quantities to power. The term was introduced in ISO 80000-1 § Annex C; it replaces and deprecates the term field quantity.

Implications

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It is essential to know which category a measurement belongs to when using decibels (dB) for comparing the levels of such quantities. A change of one bel in the level corresponds to a 10× change in power, so when comparing power quantities x and y, the difference is defined to be 10×log10(y/x) decibel. With root-power quantities, however the difference is defined as 20×log10(y/x) dB.[3]

In the analysis of signals and systems using sinusoids, field quantities and root-power quantities may be complex-valued,[4][5][6][disputeddiscuss] as in the propagation constant.

"Root-power quantity" vs. "field quantity"

[edit]

In justifying the deprecation of the term "field quantity" and instead using "root-power quantity" in the context of levels, ISO 80000 draws attention to the conflicting use of the former term to mean a quantity that depends on the position,[7] which in physics is called a field. Such a field is often called a field quantity in the literature,[citation needed] but is called a field here for clarity. Several types of field (such as the electromagnetic field) meet the definition of a root-power quantity, whereas others (such as the Poynting vector and temperature) do not. Conversely, not every root-power quantity is a field (such as the voltage on a loudspeaker).[citation needed]

See also

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References

[edit]
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Power, root-power, and field quantities

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In physics and engineering disciplines such as acoustics, electromagnetism, and electrical engineering, power quantities, root-power quantities, and field quantities provide a framework for analyzing energy transfer, signal strengths, and wave phenomena through their proportional relationships to power. A power quantity is a physical quantity directly proportional to power or requiring time averaging of its mean-square value to yield a measure proportional to power, with examples including acoustic intensity, irradiance, and Poynting vector magnitude. A root-power quantity is defined as a quantity the square of which is proportional to a power quantity in linear systems, such as voltage, current, particle velocity, and sound pressure. Field quantities, historically synonymous with root-power quantities but now deprecated as such in favor of the more precise term, refer to root-power quantities that vary with position and/or time, notably electric field strength and magnetic field strength, whose interaction determines electromagnetic power flow via the Poynting theorem. These types are essential for logarithmic measurements, particularly the scale, where levels of power quantities are expressed as 10 times the base-10 logarithm of their ratio to a reference (e.g., level), while root-power and use 20 times the logarithm to account for the squaring relation. This distinction ensures consistent comparisons across domains; for instance, in audio engineering, (a power quantity) relates to (a root-power quantity) by the square of the pressure divided by . In electromagnetics, the time-averaged is (1/2) Re(E × H*), where E and H are , highlighting their role in propagation. The standardization of these terms originated in international agreements to unify nomenclature, with "root-power quantity" formalized in ISO 80000-1:2009 to replace ambiguous usages of "field quantity" and promote clarity in multidisciplinary applications. Examples abound in practical contexts: electrical power P = V²/R, where V is root-power and R is resistance; or acoustic power proportional to the square of . Misapplying these categories can lead to errors in scaling, such as confusing the 3 dB increase for doubling power with the 6 dB increase for doubling (root-power quantity), due to the factor of 10 versus 20 in the logarithmic expression. Ongoing revisions to ISO 80000 series continue to refine these definitions for emerging fields like and .

Core Definitions

Power Quantities

Power quantities are physical quantities whose values are directly proportional to power, such as , acoustic intensity, or . These quantities represent aspects of energy transfer or distribution that scale linearly with the underlying power in a system. Mathematically, a power quantity PP relates to the physical power P\mathcal{P} by PPP \propto \mathcal{P}, or more precisely P=kPP = k \cdot \mathcal{P}, where kk is a proportionality constant depending on the specific context of measurement. In basic applications, power quantities are typically real-valued scalars that describe average power integrated over time or , providing a straightforward measure of flow without directional components. The classifies power quantities in Annex C of ISO 80000-1:2009, which addresses logarithmic quantities and their units, emphasizing their role in standardized measurement systems for consistency across disciplines like acoustics and . Root-power quantities, by contrast, are those whose squares yield power quantities in linear systems.

Root-Power Quantities

Root-power quantities are physical quantities QQ whose squares are proportional to power when acting on a linear system. This proportionality arises in contexts where dissipation or transfer depends quadratically on the quantity, such as in electrical, acoustic, or electromagnetic systems. The term "root-power quantity" was introduced in Annex C of ISO 80000-1 to provide a more precise and general descriptor, superseding the older "field quantity" terminology. Mathematically, the relation is expressed as P=kQ2P = k Q^2, where PP is power and kk is a positive constant specific to the , ensuring dimensional consistency. For example, in electrical circuits, the power dissipated in a is P=V2RP = \frac{V^2}{R}, where VV is the voltage (a root-power quantity) and RR is resistance, so k=1/Rk = 1/R. Similarly, in acoustics, the intensity II of a plane progressive wave is I=p2ρcI = \frac{p^2}{\rho c}, with pp as (another root-power quantity), ρ\rho as the medium's , and cc as the , yielding k=1/(ρc)k = 1/(\rho c). These examples illustrate how root-power quantities underpin power calculations across diverse physical domains. In analysis, root-power quantities are frequently represented as complex-valued in phasor or frequency-domain methods, taking the form Q=QeiϕQ = |Q| e^{i\phi}, where Q|Q| is the magnitude and ϕ\phi is the phase angle; the power then relates to the squared magnitude Q2|Q|^2. This complex representation facilitates handling sinusoidal signals in linear systems, such as AC circuits or wave propagation. Notably, not all root-power quantities involve spatial fields; for instance, voltage in a lumped circuit element qualifies despite lacking a field-like distribution. In contrast to power quantities, which scale directly with power, root-power quantities serve as their square-root counterparts, enabling additive superposition in linear analyses.

Terminology and Historical Development

Origin of "Field Quantity"

The term "field quantity" emerged in mid-20th century physics and , particularly within and acoustics, to characterize quantities such as strength or that exhibit field-like behavior in wave propagation contexts. In , this terminology aligned with the description of vector fields propagating through , while in acoustics, it applied to pressure variations in propagating sound waves. Early usage of "field quantity" appeared in IEEE standards prior to the 2000s and in acoustics literature, where it served to categorize amplitude-like measures—such as voltage, current, or —whose mean-square values correspond to power or intensity. For instance, in contexts, it distinguished quantities like strength from direct power measures, facilitating consistent logarithmic scaling in signal analysis. In acoustics, the term grouped measures like , emphasizing their role in deriving energy-related quantities through squaring. This nomenclature drew from foundational field theory in physics, where field magnitudes squared are directly proportional to energy density; for example, the electromagnetic energy density includes terms like 12ϵ0E2\frac{1}{2} \epsilon_0 E^2 for the electric field contribution. Analogously, in acoustics, sound intensity II relates to the square of sound pressure pp via I=p2ρcI = \frac{p^2}{\rho c}, underscoring the energetic implications of these field descriptors. Logarithmic levels for sound pressure became standardized to express ratios relative to auditory thresholds in decibel conventions for audio engineering during the 1940s and 1950s. This facilitated practical computations in electro-acoustic systems, where levels for such amplitude-like quantities used a 20 log base for ratios, contrasting with 10 log for power. The term "field quantity" was later applied to these measures and evolved into the more standardized "root-power quantity" in international norms.

Shift to "Root-Power Quantity"

The term "field quantity," originally used to describe quantities like whose squares are proportional to power quantities, has been deprecated due to its conflict with the established meaning of "field" in physics, which typically denotes position-dependent quantities such as scalar or vector fields varying with position vector r\mathbf{r}. This arises because not all such quantities are spatially distributed fields; for instance, the total voltage across a qualifies as one whose square is proportional to power but lacks the position-dependent of a true field. In response to these terminological issues, ISO 80000-1:2009, Annex C, officially recommends the adoption of "root-power " to eliminate , precisely defining it as a QQ for which the associated power is proportional to Q2Q^2 when the quantity acts on a . This change addresses disputed applications, including complex-valued quantities in , which do not inherently align with the spatial connotations of "field." This definition was retained in the 2022 edition of ISO 80000-1. The shift gained traction in international standards during the post-2000s era, with ISO 80000-1 serving as a pivotal document that influenced engineering organizations such as the (IEC) and the Institute of Electrical and Electronics Engineers (IEEE) in updating their glossaries and terminology guidelines.

Practical Implications

Decibel Level Calculations

Decibel levels are logarithmic measures used to express ratios of physical quantities relative to a reference value, with the specific scaling factor depending on whether the quantity is a power or root-power type. For power quantities, such as acoustic intensity or electrical power, the decibel level LL is calculated using the formula L=10log10(PP0) dB,L = 10 \log_{10} \left( \frac{P}{P_0} \right) \ \text{dB}, where PP represents the power quantity and P0P_0 is the reference power. This formulation arises from the definition of the bel as the logarithm base 10 of the power ratio, with the decibel being one-tenth of a bel; the factor of 10 ensures that the level corresponds directly to the logarithmic ratio of powers. The derivation ties to the fundamental logarithmic property in acoustics and , where power levels reflect ratios like sound power PP to a reference such as 11 pW. If considering the relation to squared amplitudes, note that log10(P/P0)=log10((Q2/Q02))=2log10(Q/Q0)\log_{10}(P / P_0) = \log_{10}((Q^2 / Q_0^2)) = 2 \log_{10}(Q / Q_0), but for direct power application, the 10 factor is used without the doubling. In contrast, for root-power quantities, such as , voltage, or strength, the level employs a factor of 20: L=20log10(QQ0) dB,L = 20 \log_{10} \left( \frac{Q}{Q_0} \right) \ \text{dB}, where QQ is the root-power quantity and Q0Q_0 is the . This scaling accounts for the fact that power is proportional to the square of the root-power quantity, so the power ratio logarithm is log10(P/P0)=2log10(Q/Q0)\log_{10}(P / P_0) = 2 \log_{10}(Q / Q_0), leading to 10×2=2010 \times 2 = 20 when expressing the level in relative to the root-power . For instance, in , the mean-square level can be written as Lp=10log10(p2/p02)=20log10(p/p0)L_p = 10 \log_{10} (p^2 / p_0^2) = 20 \log_{10} (p / p_0) dB re 1 μPa. Misclassification of a —such as applying the 10 log to a root-power like voltage—results in incorrect level computations, potentially invalidating subsequent analyses like reference value adjustments or system gain calculations in acoustics and . For example, using 10 log for a voltage would understate the level by a factor of 2 in the logarithm, leading to errors of 6 dB or more in practical scenarios. Standards emphasize correct identification to maintain consistency in logarithmic operations.

Usage in Linear Systems

In linear time-invariant systems, root-power quantities (historically referred to as field quantities), adhere to the , enabling the total response to be the direct vector sum of individual responses from multiple inputs. This arises because the square of a root-power is proportional to power delivered to or extracted from the system, and ensures additive behavior for these quantities themselves. For instance, in electrical circuits, the total voltage Vtotal=V1+V2V_{\text{total}} = V_1 + V_2 across a linear network from two sources, whereas the corresponding power quantities add as Ptotal=P1+P2P_{\text{total}} = P_1 + P_2 for incoherent contributions or require squaring the summed root-power values for coherent cases. Scaling properties further highlight the distinction: for a linear system with gain GG, root-power quantities scale linearly such that Qout=GQinQ_{\text{out}} = G Q_{\text{in}}, reflecting the homogeneous nature of linear transformations. In contrast, power quantities scale quadratically, Pout=G2PinP_{\text{out}} = G^2 P_{\text{in}}, since power is inherently quadratic in the root-power domain. This behavior is fundamental to system analysis, ensuring that simulations and measurements account for the appropriate quantity type to maintain accuracy. In the , root-power quantities are represented as complex-valued , facilitating phase analysis and enabling the superposition of sinusoidal components with their respective amplitudes and phases. This phasor representation preserves the linear addition of field quantities, allowing straightforward computation of system responses via transfer functions. Proper handling of these complex root-power quantities in simulations avoids errors that could arise from treating the system as nonlinear or misapplying power-based aggregation.

Applications and Examples

In Acoustics and Sound Engineering

In acoustics, acoustic intensity represents a power quantity, defined as the time-averaged power flux through a surface perpendicular to the direction of propagation. It is calculated from , a root-power quantity, using the relation for a plane progressive wave: I=p2ρcI = \frac{p^2}{\rho c}, where pp is the root-mean-square , ρ\rho is the of the medium, and cc is the . This quadratic dependence underscores why is classified as a root-power quantity, as intensity scales with the square of pressure. Sound pressure level (SPL), a common metric in sound engineering, employs the Lp=20log10(p/pref)L_p = 20 \log_{10} (p / p_{\text{ref}}), where pref=20μPap_{\text{ref}} = 20 \, \mu\text{Pa} is the reference pressure; the factor of 20 arises because is a , aligning with the logarithmic scaling for such variables. This contrasts with power quantities, which use a 10 log factor, ensuring consistent representations across acoustic measurements. Microphone sensitivity exemplifies the application of root-power quantities in sound engineering, typically specified as the output voltage (a root-power quantity, since electrical power scales with voltage squared) produced in response to a reference sound pressure of 1 Pa at 1 kHz. For instance, a condenser might exhibit a sensitivity of -40 dB re 1 V/Pa, indicating its voltage response to acoustic pressure variations in the sound field. In room acoustics, distinguishing —a power quantity representing the total acoustic emitted by a source, independent of the environment—from —a root-power quantity measured at specific points in the room—enables accurate assessment of source output versus the resulting sound field. quantifies the inherent noisiness of devices like speakers or HVAC systems, while accounts for room geometry and absorption effects on perceived levels.

In Electrical and Signal Processing

In electrical engineering and signal processing, power quantities represent the rate of energy transfer, such as electrical power PP, which is defined as the product of voltage VV and current II, or equivalently P=V2RP = \frac{V^2}{R} where RR is resistance, illustrating that voltage and current are root-power quantities whose squares are proportional to power. Root-power quantities like voltage and current are fundamental because their magnitudes scale with the square root of the corresponding power; for instance, doubling the voltage across a fixed resistance quadruples the power dissipated, as PV2P \propto V^2. This distinction is critical in circuit analysis, where power quantities quantify energy flow while root-power quantities like voltage describe field-like amplitudes in signals. Voltage levels in audio signals are commonly expressed in decibels using the formula 20log10(VV0)20 \log_{10} \left( \frac{V}{V_0} \right) dB, where VV is the RMS voltage and V0V_0 is a reference voltage (often 1 V for dBV), reflecting the root-power nature of voltage since power ratios convert via the factor of 20 to account for the quadratic relationship. This scaling ensures that a 20 dB increase corresponds to a tenfold voltage rise, aligning with perceptual and measurement standards in audio processing. In amplifiers, root-power quantities enable linear scaling: the output voltage scales directly with the input voltage according to the voltage gain AvA_v, but the power gain is quadratic, given by Ap=Av2A_p = A_v^2 when input and output impedances match, as power is proportional to the square of voltage. For example, an with a voltage gain of 10 produces a of 100 (or 20 dB), emphasizing how root-power handling simplifies design for linear systems while power considerations reveal efficiency limits. In , the root-mean-square (RMS) voltage serves as a key root-power quantity for characterizing floors, representing the effective of noise that, when squared and averaged, yields the contrasting with the total signal power, which integrates over the full bandwidth. This approach allows precise quantification of , such as in analog-to-digital converters where the in RMS voltage determines the , distinguishing it from aggregate signal power metrics used for overall .

References

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