Fact-checked by Grok 2 weeks ago

Circular segment

A circular segment is a portion of a disk bounded by a chord and the corresponding arc of the circle, typically defined for a central angle θ less than or equal to π radians (180 degrees), distinguishing it from the larger segment when θ exceeds π.^[1] This geometric figure, first described in ancient texts as "the figure contained by a straight line and a circumference of a circle," has been a fundamental concept in geometry since Euclid's Elements around 300 BCE.^[2] Key properties of a circular segment include its area, chord length, sagitta (height), and arc length, all derived from the circle's radius R and the central angle θ. The area A is given by the formula A = \frac{1}{2} R^2 (\theta - \sin \theta), where θ is in radians, representing the difference between the sector area and the triangular portion.^[1] The chord length a measures a = 2R \sin(\theta/2), while the sagitta h (the perpendicular distance from the chord midpoint to the arc) is h = R (1 - \cos(\theta/2)).^[1] The arc length s simply equals s = R \theta.^[1] Circular segments find practical applications across engineering and design fields, such as calculating the volume of liquid in partially filled horizontal cylindrical tanks in hydraulics, where the cross-sectional area is a segment.^[1] In architecture, they inform the design of arched structures like windows, doorways, and vaults for both aesthetic and structural integrity.^[3] Circular segments are also used in mechanics and optics.^[1] Historically, circular segments appeared in Japanese temple geometry (sangaku) problems of the Edo period (1603–1868), solving area-related puzzles.^[1]

Introduction

Definition

A circular segment is the region of a disk bounded by a chord and the corresponding arc subtended by that chord, specifically the portion where the central angle is less than \pi radians to denote the smaller area.^[1] Visually, it appears as a cap-like area cut off from the rest of the disk by the straight chord line.^[1] The minor segment, corresponding to the arc less than a semicircle, is the standard reference unless the major segment is explicitly indicated.^[1] This region differs from a circular sector, which includes the triangular area formed by the two radii to the chord's endpoints and the arc, whereas the segment excludes that triangle.^[1] It also contrasts with the full disk, representing only a partial area enclosed by the circle's boundary.^[1] Common parameters include the circle's radius r, the central angle \theta in radians, the chord length c, and the sagitta h (the perpendicular distance from the chord's midpoint to the arc).^[1] The central angle and chord serve as fundamental components defining the segment's shape.^[1]

Historical Background

The concept of the circular segment traces its origins to ancient civilizations, where early approximations for its area appeared in Babylonian mathematics around the late 5th century BCE and in 3rd-century BCE Egyptian papyri, often employing simple trapezoidal or triangular estimates assuming a value of π close to 3. These practical methods were geared toward architectural and measurement tasks, such as inscribing segments within polygons.^[4] Archimedes of Syracuse contributed foundational insights in his treatise On the Measurement of a Circle (c. 250 BCE), establishing the circle's area as equal to that of a right triangle with one leg equal to the radius and the other to the circumference, which provided a rigorous basis for later segment derivations, though he focused more broadly on circular areas and parabolic segments. His mechanical method of exhaustion influenced subsequent geometric treatments.^[4] The systematic development of circular segment theory is primarily attributed to Hero of Alexandria (c. 10–70 CE) in Book I of his Metrica, where he outlined four distinct procedures for computing the segment's area using the chord length (base b) and sagitta (height h). These included the "ancient method," a basic trapezoidal approximation suitable for modest segments; a "revised method" adjusting for a more precise π ≈ 3 1/7; a "quasi-Archimedean method" drawing from Archimedes' parabolic quadrature for flatter segments (where b > 3h); and a "subtraction method" for deeper segments (h > r), subtracting the smaller complementary segment from the full circle's area. Hero's approaches blended geometric constructions, such as inscribing isosceles triangles via the Pythagorean theorem, with empirical approximations, bridging practical engineering needs—like aqueduct and vessel design—with theoretical rigor.^[4] During the medieval Islamic Golden Age, scholars preserved and refined Greek geometric traditions through translations and commentaries, advancing quadrature techniques for circular figures, including segment-like divisions via inscribed polygons and trigonometric methods. Figures such as Jamshid al-Kashi (c. 1380–1429) in his Treatise on the Chord (1424) enhanced approximations for circular arcs and areas by computing π to 16 decimal places using polygonal perimeters, which facilitated more accurate segment calculations in astronomical and architectural contexts.^[5]^[6] These trigonometric advancements allowed for exact formulas using sine functions, further developing segment theory. The Renaissance saw European mathematicians adopt these Islamic-transmitted works, integrating segment methods into emerging fields like perspective and fortification design. By the 19th century, analytic geometry formalized the circular segment in standard textbooks, expressing it through trigonometric and coordinate-based relations for precise engineering applications, evolving from ancient approximations to proofs grounded in calculus and limits.^[4]

Geometry

Components and Terminology

A circular segment is composed of several key geometric elements that define its structure. The chord is the straight line segment connecting the two endpoints of the arc, serving as the base of the segment and denoted by its length c.^[1] This chord divides the circle into the segment and the remaining portion. The arc forms the curved boundary of the segment, representing the portion of the circle's circumference between the chord's endpoints and subtending a central angle \theta at the circle's center.^[1] The sagitta, or height h, is the perpendicular distance from the midpoint of the chord to the midpoint of the arc, measuring the "depth" or bulge of the segment.^[7] The radius r is the fixed distance from the circle's center to any point on the arc, determining the overall scale of the segment.^[1] Segments are classified as minor when \theta < \pi radians (less than 180 degrees), forming the smaller cap away from the center, or major when \theta > \pi, encompassing the larger portion including the center; by convention, discussions focus on the minor segment.^[1] Additionally, the chord and the two radii to its endpoints form an isosceles triangle, which provides a foundational geometric relation for understanding the segment's position relative to the circle's center.^[1] These components interconnect through basic trigonometry, as explored in subsequent relations.

Basic Relations

A circular segment is defined by its chord, which subtends a central angle \theta at the circle's center. The length of the chord c is given by the formula c = 2 r \sin\left(\frac{\theta}{2}\right), where r is the radius of the circle; this relation arises from considering the isosceles triangle formed by the two radii to the chord endpoints and the chord itself, where the right triangle half of this isosceles triangle has opposite side c/2 to the angle \theta/2.^[1]^[8] The sagitta h, or height of the segment, measures the perpendicular distance from the chord's midpoint to the arc's midpoint. It is expressed as h = r \left(1 - \cos\left(\frac{\theta}{2}\right)\right), derived by subtracting the projection of the radius along the perpendicular bisector from the full radius.^[1]^[8] The position of the circle's center relative to the chord is determined by the signed distance d from the center to the chord, given by d = r \cos\left(\frac{\theta}{2}\right); here, d is positive when the center lies on the side of the major arc (for \theta < \pi) and negative otherwise, indicating the side of the chord where the center resides.^[1] For the minor segment, the sagitta relates to this distance as h = r - d when d > 0.^[9] These components satisfy a Pythagorean relation in the right triangle formed by the radius to a chord endpoint, half the chord length, and the distance from the center to the chord: \left(\frac{c}{2}\right)^2 + d^2 = r^2. Substituting d = r - h for the minor segment yields the alternative form \left(\frac{c}{2}\right)^2 + h^2 = 2 r h, which connects the chord, sagitta, and radius directly.^[1]^[9] In all these relations, the central angle \theta is measured in radians, as the trigonometric functions in the formulas are defined accordingly; to convert from degrees, multiply by \pi / 180. These basic relations form the foundation for computing other segment properties, such as area.^[1]

Formulas

Area

The area A of a circular segment is given by the formula

A = \frac{1}{2} r^2 (\theta - \sin \theta),

where r is the radius of the circle and \theta is the central angle subtended by the chord in radians.^[1] This formula is derived by subtracting the area of the isosceles triangle formed by the two radii and the chord from the area of the circular sector bounded by the two radii and the arc. The sector area is \frac{1}{2} r^2 \theta, and the triangle area is \frac{1}{2} r^2 \sin \theta, yielding the difference \frac{1}{2} r^2 (\theta - \sin \theta).^[1] An alternative expression uses the sagitta (height) h of the segment and the radius r, where \theta = 2 \arccos\left(1 - \frac{h}{r}\right). Substituting these relations into the standard formula gives

A = r^2 \arccos\left(\frac{r - h}{r}\right) - (r - h) \sqrt{2 r h - h^2}.

^[1] When the chord length c is known along with h, the radius can first be found from r = \frac{h^2 + (c/2)^2}{2 h}, after which the area is computed using the height-based form above.^[1] In antiquity, Hero of Alexandria provided methods for the area in terms of chord length b (equivalent to c) and height h, including an approximate formula for segments less than a semicircle: A \approx h \cdot \frac{b + h}{2} + \frac{(b/2)^2}{14}. For exact computation, Hero's procedures involved geometric constructions leading to the trigonometric relations underlying the modern formula.^[4]^[10] The area is expressed in square units consistent with the units of the radius r.^[1]

Arc Length and Perimeter

The arc length s of a circular segment is the measure of the curved portion of the circle's circumference that bounds the segment. For a minor segment subtended by a central angle \theta in radians, this length is given by the formula s = r \theta, where r is the radius of the circle.^[1] This formula applies specifically when \theta \leq \pi, focusing on the shorter arc typical of minor segments.^[11] The derivation of the arc length formula stems from the proportional relationship between the angle and the full circumference of the circle. The complete circumference is $2\pi r, corresponding to a full central angle of $2\pi radians; thus, the arc length is the proportion of the circumference subtended by \theta, yielding s = \frac{\theta}{2\pi} \cdot 2\pi r = r \theta.^[12] This arc length serves as a key boundary component of the segment, enclosing the area along with the chord.^[1] The perimeter P of a circular segment is the total length of its boundary, comprising the arc length s and the straight chord length c. Therefore, P = c + r \theta.^[11] The chord length c is determined from the geometric relation between the radius and the central angle, as detailed in the Basic Relations section.^[1] For a major segment, where the central angle exceeds \pi radians, the arc length adjusts to the longer portion of the circumference, but the primary focus here remains on minor segments.^[11]

Parameter Conversions

In circular segments, parameter conversions enable the determination of one geometric measure—such as the radius r, central angle \theta (in radians), sagitta h, or chord length c—from the others using fundamental trigonometric and Pythagorean relations. These conversions are essential for practical computations in engineering and design where not all parameters are directly measured.^[1] To solve for the radius r given the chord length c and sagitta h, apply the Pythagorean theorem to the right triangle formed by the radius, the line from the circle's center to the chord's midpoint (of length r - h), and half the chord (of length c/2). This yields the explicit formula:

r = \frac{c^2}{8h} + \frac{h}{2}

This algebraic expression is derived directly from expanding (c/2)^2 + (r - h)^2 = r^2 and solving for r.^[1]^[13] For the central angle \theta given the sagitta h and radius r, use the cosine relation in the isosceles triangle subtended by the chord. The half-angle satisfies \cos(\theta/2) = 1 - h/r, so:

\theta = 2 \arccos\left(1 - \frac{h}{r}\right)

This relies on the inverse cosine function, which is well-defined for $0 < h \leq 2r where the argument lies in [-1, 1].^[1] Conversely, to find the chord length c given the radius r and central angle \theta, apply the chord formula from the isosceles triangle:

c = 2 r \sin\left(\frac{\theta}{2}\right)

This trigonometric identity follows from the law of sines or the geometry of the segment.^[1]^[13] To obtain the sagitta h from the radius r and central angle \theta, use the vertical projection in the same triangle:

h = r \left(1 - \cos\left(\frac{\theta}{2}\right)\right)

This expression derives from subtracting the y-coordinate of the chord's midpoint from the radius.^[1]^[13] Numerical implementation of these conversions involves standard library functions for sine, cosine, and inverse cosine, which are accurate for most cases. However, in complex scenarios—such as when h is very small relative to r (leading to arguments near 1 in arccos) or when floating-point precision causes cancellation errors—iterative refinement methods like Newton-Raphson may be necessary to achieve reliable results. These build on the core relations detailed elsewhere.^[1]

Properties and Approximations

Geometric Properties

A circular segment possesses bilateral symmetry about the perpendicular bisector of its chord, which also passes through the center of the enclosing circle, dividing the segment into two mirror-image halves. This symmetry arises from the uniform radial structure of the circle and ensures that corresponding points on either side of the bisector are equidistant from it.^[1] The chord and the two radii connecting its endpoints to the circle's center form an isosceles triangle, where the apex angle at the center equals the central angle subtended by the arc. This triangular configuration underpins many geometric relations of the segment, highlighting its inherent balance.^[1] (Beyer 1987) At the endpoints of the chord, the tangent lines to the arc are perpendicular to the radii drawn from the center to those points, a fundamental property of circles that defines the arc's boundary behavior. The segment's interior, bounded by the curved arc and straight chord, lacks a uniform tangent across its entirety due to the differing natures of its boundaries—the arc permits localized tangents, while the chord, being linear, aligns with its own direction as a tangent.^[14] The curvature along the arc portion of the segment's boundary remains constant, equal to the reciprocal of the circle's radius, reflecting the circle's intrinsic roundness. In contrast, the chord exhibits zero curvature as a straight line segment. A circular segment represents one part of the disk divided by the chord, with the complementary major segment completing the full disk when combined.^[1]^[15]

Approximations

Approximations for the area of a circular segment are particularly valuable when the central angle θ is small or when computational efficiency is prioritized over exact calculations, such as in engineering estimates or software implementations. These methods often rely on series expansions or simplified geometric relations to provide quick results with controlled error. For small central angles (θ ≪ 1 radian), the area A can be approximated using the Taylor expansion of the exact area formula A = (r²/2)(θ - sin θ). Substituting the series sin θ ≈ θ - θ³/6 yields θ - sin θ ≈ θ³/6, so A ≈ (r² θ³)/12.^[1] In terms of the sagitta h (the height of the segment), where h ≈ r θ²/8 for small θ, and the chord length c ≈ r θ, this becomes A ≈ (2/3) c h. This linear approximation treats the segment similarly to a parabolic one and is accurate to within a few percent for shallow segments where h ≪ r.^[1] A more refined approximation for the area, applicable to a wider range of angles, is A ≈ (2/3) c h + h³/(2 c), which incorporates a cubic correction term and achieves relative errors less than 0.1% for θ up to approximately 150° and less than 0.8% up to 180°. This formula, derived from geometric series considerations, is documented in mathematical handbooks for practical computations.^[1] Historically, Hero of Alexandria in his work Metrica (ca. 60 AD) provided early approximations for shallow circular segments, including a simple linear formula equivalent to A ≈ (2/3) b h (where b is the base chord length), suitable for segments much smaller than a semicircle. Hero offered multiple methods, with this one serving as a basic estimate based on geometric proportions known from earlier traditions.^[4] Error analysis for small-angle approximations shows that the relative error in A ≈ (r² θ³)/12 is on the order of θ²/20, derived from the next term in the Taylor series -(r² θ⁵)/240; for θ = 0.5 radians (≈28.6°), the error is about 1.3%, decreasing rapidly for smaller θ. For the (2/3) c h formula, errors are typically under 1% when h/r < 0.1 but grow for deeper segments, necessitating higher-order terms for precision.^[1] In modern applications, these approximations facilitate rapid estimates in numerical methods and CAD software, where exact inverse trigonometric functions may be avoided for real-time rendering or optimization; for instance, shallow segment approximations speed up simulations in structural analysis without significant loss of accuracy.^[1]

Applications

Structural Engineering

In structural engineering, circular segments play a key role in the design and analysis of arches and bridges, particularly for estimating material volumes in circular or segmental arch constructions. The cross-sectional area of a circular segment represents the solid portion between the chord and arc, which, when multiplied by the arch's length or span, yields the total volume of materials such as masonry, concrete, or steel required. This calculation is essential for optimizing resource allocation and ensuring structural efficiency in load-bearing elements. For example, in segmental arches common to bridge spans, engineers use segment area formulas to quantify brick or concrete quantities, minimizing waste while maintaining compressive strength under vertical loads.^[16] Circular segments are used in the analysis of curved arch dams, where hydrostatic pressures on the curved surfaces are considered in stability assessments, including uplift, sliding, and overturning. These analyses account for water pressure variations with depth, ensuring the structure efficiently transfers loads to the abutments via compressive arch action. Representative designs, such as those analyzed in U.S. Army Corps of Engineers guidelines, demonstrate how approximations of curved profiles simplify finite element modeling for seismic and flood loading scenarios, prioritizing safety factors in high-head reservoirs.^[17]^[18] In pipe and tunnel design, circular segments define the cross-sectional flow area for partially filled conduits, critical for hydraulic capacity in gravity-flow systems like sewers, culverts, and utility tunnels. The segment area determines the wetted perimeter and hydraulic radius, enabling Manning's equation computations for velocity and discharge under varying fill ratios, often below 80% to avoid surcharging. This approach is standard in stormwater management, where segment geometry predicts sediment transport and self-cleansing velocities, as seen in designs for urban drainage networks. For tunnels with circular cross-sections, such as those in subway or irrigation systems, partial filling due to operational levels requires segment calculations to balance structural loads from soil overburden and internal pressures.^[19]^[20] In the design of storage tanks, circular segments are used to calculate the cross-sectional area of liquid in partially filled horizontal cylindrical tanks, aiding in volume estimation for hydraulics and inventory management.^[1] Stress analysis in segment-shaped beams, prevalent in arched frameworks, involves computing bending moments to evaluate tensile and compressive stresses across the curved profile. Unlike straight beams, these members exhibit nonlinear stress distribution due to varying fiber lengths, necessitating Winkler-Bach theory for accurate predictions of maximum stresses at inner and outer radii. In applications like bridge girders or vault ribs, engineers apply moment-curvature relations to segment cross-sections, ensuring fatigue resistance under cyclic loads. The segment area provides the basis for volume in these volume-dependent strength assessments, as outlined in the Area section.^[21] Historically, Hero of Alexandria's geometric methods for circular segments, detailed in his treatises on mechanics and stereometry, influenced ancient engineering for vaults and arches by providing calculable areas for material planning and formwork. These techniques supported Roman vault constructions, such as those in imperial baths and basilicas, where segment approximations ensured proportional load distribution in voussoir assemblies.^[22]

Manufacturing and Design

In manufacturing, circular segments play a key role in gear tooth profiles and cam mechanisms, where the curved shapes are designed using segment geometry to ensure smooth motion and precise engagement.^[1] Circular segment cutters have emerged as a specialized tool for finishing complex mold surfaces, particularly in aerospace applications where precision and efficiency are critical. These cutters feature a cutting edge formed as a segment of a larger radius arc, allowing for shallower engagement angles compared to traditional ball nose end mills, which results in reduced cusp heights and fewer passes required for surface finishing.^[23] For instance, in machining titanium aerospace components, circle segment end mills can reduce cycle times by 50-70% over ball nose tools by enabling higher stepover distances while maintaining surface quality, as demonstrated in mold prototyping where processing time dropped from over 9 hours to approximately 1 hour.^[24] This efficiency gain also extends tool life by minimizing heat buildup and wear, making them ideal for high-volume production of contoured parts like turbine blades.^[25] In computer-aided design (CAD) and graphics software, circular segments are integral to rendering precise geometric shapes for components such as wheel rims, optical lenses, and user interface elements. Software like Autodesk Fusion 360 and SolidWorks employs circular segment profiles to model wheel designs, where arcs and chords define spoke patterns and rim contours through revolve and pattern tools, ensuring accurate 3D visualization and simulation.^[26] Similarly, in optical CAD systems, segment calculations facilitate the design of lens profiles by approximating aspheric surfaces via sagitta measurements—the height of the circular segment—which informs curvature deviations for aberration correction.^[27] For UI elements, vector-based rendering in tools like Adobe Illustrator uses circular segments to create segmented arcs for progress indicators or pie charts, optimizing scalability without pixelation.^[28] Architectural design incorporates circular segments for decorative elements that enhance aesthetic harmony and structural elegance. Rose windows in Gothic cathedrals, such as those in the Basilica of Saint Francis in Assisi, rely on proportional segmentation of concentric circular rings—often divided into 12, 14, or 44 parts using ratios like 22:7—to create intricate radial patterns that balance light diffusion and visual symmetry.^[29] Fan vaults, a hallmark of late English Gothic architecture like those in Gloucester Cathedral's cloister, utilize converging single constant-curvature circular arcs to form radiating rib patterns, allowing for expansive, lightweight ceilings with uniform curvature that distributes visual weight evenly; later examples employ Tudor arcs composed of two circular segments.^[30] In optical design and lens manufacturing, circular segment areas play a key role in fabricating aspheric surfaces, where the segment's sagitta quantifies the deviation from a spherical profile to minimize aberrations in high-performance lenses. This parameter guides precision grinding and polishing processes, ensuring the lens's non-constant radius aligns with design specifications for applications like camera objectives or medical endoscopes, as the area calculation helps optimize material removal and surface form accuracy.^[27] Modern CNC programming leverages circular segment approximations to generate efficient tool paths, particularly for complex contours in pocket machining. By dividing free-form paths into linear and circular segments, programmers reduce data points and machining interruptions, with shorter segment lengths shown to lower actual cutting times by up to 20% compared to longer approximations, though excessive segmentation can increase non-cutting moves.^[31] This approach, implemented via G02/G03 codes for circular interpolation, enhances path smoothness in five-axis systems, briefly referencing CAD approximations for initial path generation without altering core geometric computations.^[32] Circular segments have historical applications in Japanese temple geometry problems of the 18th century, where they were used to solve area-related puzzles in traditional sangaku (wooden tablet) mathematics.^[1]

References

[1]
Circular Segment -- from Wolfram MathWorld
A circular segment is a portion of a disk whose upper boundary is a (circular) arc and whose lower boundary is a chord making a central angle theta.
[2]
Euclid's Elements, Book III, Definitions 6 through 9 - Clark University
Definition 6: A segment of a circle is the figure contained by a straight line and a circumference of a circle.
[3]
Segment of a Circle calculator and formulas - RedCrab
Applications of Circular Segments · Architecture & Construction · Mechanical Engineering & Technology · Optics & Lighting · Hydraulics & Water Engineering.
[4]
Hero and the tradition of the circle segment
Jul 24, 2023 · For Archimedes showed in the Method every segment enclosed by a straight-line and section of a right-angled cone, that is of a parabola, is a ...
[5]
Glimpses in the History of a Great Number: Pi in Arabic Mathematics
Sep 22, 2008 · Al-Kāshī measured the circumference of an equal-sided angular figure that is surrounded by a circle, and another that is surrounded by a circle ...Missing: segment | Show results with:segment
[6]
Research - Revisiting the Squinch: From Squaring the Circle to ...
Jun 2, 2012 · Ghiyath al-Din Jamshid Kashani (1380-1429), known as al-Kashi, Persian Islamic scientist and geometer of the fifteenth century, extensively ...<|control11|><|separator|>
[7]
Sagitta definition with calculator - Math Open Reference
The sagitta is the vertical line from the midpoint of the chord to the arc itself. It is a measure of the 'height' of the arc.Missing: notation symbol parameters θ h
[8]
Circular Segment Equation and Calculator - Engineers Edge
The area A of the circular segment is equal to the area of the circular sector minus the area of the triangular portion. θ given in radians. A = (R2 / 2 ) ( θ - ...Missing: notation symbol parameters
[9]
Geometric properties of circular segment | calcresource
Jan 18, 2022 · This tool calculates the basic geometric properties of a circular segment. Enter below the circle radius R and either one of: central angle φ or height h or ...
[10]
[PDF] Compendium copy 3 - HAL
Criterion for establishing the species of a circular segment: if h = 1⁄2(b) ... Hero of Alexandria, Metrica = F. ACERBI – B. VITRAC, Héron d'Alexandrie ...
[11]
Segment of a Circle – Definition, Formulas, Examples - Math Monks
Jul 29, 2021 · A segment of a circle is the region bounded by a chord of the circle and its associated arc. It is represented by the symbol '⌓'.Missing: parameters sagitta
[12]
[PDF] Math 109 T4–Arc Length and Radian Measure Review Page 1
the corresponding arc length is the circumference of the circle, 2πr. Using proportions, we have r θ s angle arc length. = one revolution circumference. , or.Missing: derivation | Show results with:derivation
[13]
None
### Summary of Circular Segment Formulas from Appendix E - Plane Geometry
[14]
[PDF] Circle Definitions and Theorems
DEFINITIONS. Circle- The set of points in a plane equidistant from a given point(the center of the circle). Radius- A segment from the center of the circle ...
[15]
3.3 Arc Length and Curvature - Calculus Volume 3 | OpenStax
Mar 30, 2016 · The concept of curvature provides a way to measure how sharply a smooth curve turns. A circle has constant curvature. The smaller the radius of ...
[16]
Calculate Quantity Of Materials In Segmental Arch
In this civil engineering article, you will learn the calculation process for determining the quantity of materials in a segmental arch.
[17]
[PDF] Technical Notes 31 - Brick Masonry Arches
Jack, segmental, semicircular and multicentered arches are the most common types used for building arches. For very long spans and for bridges, semicircular ...
[18]
[PDF] CHAPTER 11 - ARCH DAMS
Hydrostatic Pressure - The stability of an abutment rock wedge is affected by the hydrostatic ... pressure for circular jets is calculated with. Equation 11A-30, ...
[19]
[PDF] EM 1110-2-2201 - USACE Publications
May 31, 1994 · This manual provides information and guidance on the design, analysis, and construction of concrete arch dams. 2. Applicability. This manual ...
[20]
Partially Full Pipe Flow Calculator and Equations - Engineers Edge
Partially Full Pipe Flow Calculator - This engineering calculator determines the Flow within a partially full pipe using the Manning equation.Missing: tunnel | Show results with:tunnel
[21]
https://files.engineering.com/download.aspx?folder=96a7f4c6-0d20-4f0c-8573-260b80e2e80f&file=Curved_Beams.pdf
[22]
[PDF] Beams curved in plan - Engineering.com
Tables and formulas for the calculation of bending and torsional moments, shear, and deflections for different cases of loadings on curved beams and rings are ...<|control11|><|separator|>
[23]
On Vaulting: Heron's Manuals and Their Role in Roman Dome Design
Apr 2, 2024 · In this paper we focus on the relationship between Heron of Alexandria's manuals and the vaulting systems of the Hadrianic age.
[24]
Understanding Circle-Segment Milling Tools - Modern Machine Shop
Jul 2, 2018 · Circle-segment tools finish surfaces significantly more productively than ballnose tools by cutting with an edge that is larger in radius than the ballnose's ...
[25]
[PDF] A Closer Look at 5-Axis Machining with Circle Segment End Mills
It is important to note that the ball nose end mill took approximately 9 hours and 36 minutes to complete, whereas the Circle Segment End Mills took an ...
[26]
Circle Segment Tools vs. Ball Nose End Mills
The key advantage of circle segment tools is their ability to significantly reduce finish-milling times while improving surface finishes, making them ideal for ...<|control11|><|separator|>
[27]
How to design a Car wheel rim on Autodesk Fusion 360 - YouTube
Dec 4, 2019 · Autodesk Fusion 360 tutorial showing how to design a Car wheel rim in simple steps. Tools used in this video are 1. Revolve 2. Circular ...
[28]
The Complete Guide to Aspheric Lens (ASP Lens) - Avantier Inc.
The definition of rotationally symmetric aspheres often involves a surface sagitta (the measure of the surface shape in relation to a plane), or sag, expressed ...
[29]
Circles, arcs, and curves are not displayed smooth in AutoCAD ...
Jun 10, 2025 · Circles, arcs, and curves in AutoCAD products may not appear round or smooth. Instead, these elements can display as segmented lines, jagged edges, chunky ...
[30]
[PDF] ROSE WINDOWS IN GOTHIC CATHEDRALS: A COMPOSITIONAL ...
The ratio of 22:7 explains the segmentation of circular rings in the Basilica of Saint Francis in Assisi into. 12, 14, and 44 parts. With the aid of a module it ...Missing: fan vaults
[31]
Statics of fan vaulting: current state of knowledge and open issues
Feb 24, 2021 · Fan vaults, the most spectacular structural form of the English Gothic architecture ... circular segments ('Tudor arc', see later). (ii).Definition · Origins of fan vaulting · Main periods of fan vaulting · Statics of fan vaults
[32]
(PDF) Cutting time in pocket machining for different tool-path ...
Aug 9, 2025 · The study, conducted in two different milling machines, shows how shorter segments increase the actual cutting time, which is lower for G01 than ...<|control11|><|separator|>
[33]
[PDF] Approximation Method of Tool Path Oriented to Five-axis CNC ...
In order to guide the CNC machine to perform cutting along the CL path or tool path, the path is traditionally divided into a set of line or circular segments.Missing: programming | Show results with:programming