Equal Earth projection
The Equal Earth projection is an equal-area pseudocylindrical map projection for world maps, developed in 2018 by Bojan Šavrič of Esri, Tom Patterson of the US National Park Service, and Bernhard Jenny of Monash University.[1][2] It preserves the true relative sizes of continents, oceans, and countries while aiming for a visually balanced and globe-like appearance that avoids the extreme distortions in shape common to other equal-area projections such as the Gall-Peters.[1][2] Inspired by the non-equal-area Robinson projection's aesthetic qualities, Equal Earth incorporates curved meridians suggestive of the Earth's sphericity and straight latitude parallels to facilitate easy visual comparison of positions.[1][2] The projection's mathematical formulation was derived to minimize angular distortion for land features, making it suitable for thematic world mapping and general reference where area accuracy is prioritized over conformal shape preservation.[2] Since its introduction, it has gained adoption in geographic information systems software like ArcGIS and PROJ libraries, as well as in educational and institutional maps seeking alternatives to size-distorting projections like Mercator.[3][4]History
Development and Introduction
The Equal Earth projection was jointly developed by cartographers Bojan Šavrič of Esri, Bernhard Jenny of Monash University, and Tom Patterson of the United States National Park Service.[1][2] The development process comprised two principal phases: an initial graphical design stage, in which the creators employed a custom software tool to iteratively blend two parametric curves—one defining the horizontal scale factor and the other the vertical scale factor—to achieve a pseudocylindrical form that visually approximates the globe's rounded continents and polar regions while strictly maintaining equal-area preservation.[2] This aesthetic goal drew inspiration from the non-equal-area Robinson projection's popularity for world maps, but prioritized area fidelity over compromise distortions.[2][5] Following the graphical prototyping, the team derived an analytical formulation by regressing a ninth-degree odd-powered polynomial to fit the y-coordinate as a monotonic function of a transformed latitude parameter, ensuring computational efficiency and reversibility for mapping applications; the coefficients were optimized as A_1 = 1.340264, A_2 = -0.081106, A_3 = 0.000893, and A_4 = 0.003796.[2] This polynomial approximation yielded a projection with continental outlines that enlarge smoothly toward the equator, contrasting with the pinched polar regions common in many equal-area cylindrical or pseudocylindrical designs.[2] The effort was spurred by 2017 media coverage of educational initiatives, such as Boston Public Schools' adoption of the Gall–Peters projection, which highlighted demands for equal-area representations but critiqued its unflattering continental elongations.[2][5] The projection was formally introduced through the publication of the paper "The Equal Earth map projection" in the International Journal of Geographical Information Science on August 13, 2018, accompanied by open-source code and a dedicated website (equal-earth.com) providing implementations in formats compatible with GIS software like ArcGIS and QGIS.[2][1] Early dissemination included presentations at cartographic conferences, such as the 2018 International Cartographic Conference, where the designers emphasized its balance of area accuracy and perceptual uniformity for thematic world mapping.[6] By late 2018, it had garnered attention in professional mapping communities as a viable alternative to legacy equal-area projections, with implementations integrated into major software suites.[5]Motivations from Prior Projections
The Equal Earth projection emerged from dissatisfaction with the trade-offs in prior world map projections, particularly the visual compromises required for equal-area preservation. The Robinson projection, developed by Arthur H. Robinson in 1963 and adopted by the National Geographic Society in 1988, achieved widespread use due to its aesthetically balanced continental outlines and globe-like curvature, appearing in the majority of world maps across 11 English-language and one Russian atlas examined from 2000 to 2011. However, as a compromise projection, it systematically enlarges polar and high-latitude areas—such as Greenland appearing comparable in size to Africa—while shrinking equatorial regions, violating equal-area principles essential for thematic mapping of quantities like population density or land cover.[2] This area distortion prompted cartographers Bojan Šavrič, Tomaž Ertič, and Bernhard Jenny to seek an equal-area alternative that retained Robinson's familiar shapes. Traditional equal-area pseudocylindrical projections, including the Mollweide projection (Karl B. Mollweide, 1805, revised 1857) and Eckert IV (Max Eckert-Greiffendorff, 1906), preserve areas but produce elliptical boundaries and horizontally compressed high latitudes, resulting in squat polar continents and less intuitive outlines compared to the globe. Similarly, the Gall–Peters projection (James Gall, 1855; Arno Peters, popularized 1973), which stretches landmasses vertically to enforce equal areas, yields elongated, unfamiliar shapes that many cartographers and users find visually unappealing despite its advocacy for equitable representation.[2] A catalyst was the March 2017 decision by Boston Public Schools to replace Mercator-based maps with Gall–Peters, sparking media debates on projection biases and renewing calls for equal-area maps suitable for education. Šavrič et al. addressed these by graphically blending elements of Eckert IV and Putniņš P4' (1927)—both equal-area but with differing curvatures—in a web application, iteratively adjusting to approximate Robinson's boundary while enforcing area fidelity through polynomial equations. This approach prioritized mid-latitude shape preservation, reducing the polar compression and edge waving seen in sinusoidal or Bonne projections, to yield a projection deemed more suitable for general-purpose world mapping.[2][7]Initial Publication and Early Response
The Equal Earth projection was developed by cartographers Bojan Šavrič, Tom Patterson, and Bernhard Jenny, with its initial online publication occurring in August 2018.[8] The creators detailed the projection in an accompanying paper, "Introducing the Equal Earth Projection," emphasizing its pseudocylindrical design inspired by the Robinson projection but modified to ensure equal-area preservation through polynomial approximations of latitude.[9] This work was explicitly positioned as a counter to the recent institutional adoption of the Gall–Peters projection, such as by Boston Public Schools in March 2017, which prioritized area accuracy at the expense of continental shapes resembling a globe.[9] Early reception within cartographic circles was favorable, with commentators noting the projection's balanced aesthetics—featuring elliptical meridians and evenly spaced parallels that evoke a spherical form without sacrificing area fidelity.[10] By late 2018, implementations appeared in open-source libraries like D3.js and PROJ, facilitating rapid integration into digital mapping tools.[11] A follow-up analysis in 2019 documented over 1,000 social media mentions within months of release, predominantly positive, and highlighted its potential as a standard for reference maps in atlases and software defaults.[11] No significant criticisms of its mathematical validity emerged initially, though some observers contrasted its compromise on angular fidelity with purely conformal alternatives.[12]Mathematical Formulation
Core Equations
The forward projection of the Equal Earth map projection transforms geographic coordinates of longitude \lambda and latitude \varphi (in radians) into plane coordinates x and y.[13] An intermediate parametric latitude \theta is defined by \sin \theta = \frac{\sqrt{3}}{2} \sin \varphi, which can be solved directly as \theta = \arcsin\left(\frac{\sqrt{3}}{2} \sin \varphi\right) since \left|\frac{\sqrt{3}}{2} \sin \varphi\right| \leq \frac{\sqrt{3}}{2} < 1.[13] This relation ensures the projection's pseudocylindrical form, where meridians are equally spaced straight lines and parallels are curved. The x-coordinate scales linearly with \lambda at constant \theta: x = \frac{2\sqrt{3} \, \lambda \, \cos \theta}{3(9A_4 \theta^8 + 7A_3 \theta^6 + 3A_2 \theta^2 + A_1)}. The y-coordinate follows a ninth-degree polynomial in \theta: y = A_4 \theta^9 + A_3 \theta^7 + A_2 \theta^3 + A_1 \theta. These forms derive from numerical optimization to enforce equal-area preservation, \iint \cos \varphi \, d\varphi \, d\lambda = \iint dx \, dy, while minimizing shape distortion akin to the Robinson projection.[13] The fitted coefficients are A_1 = 1.340264, A_2 = -0.081106, A_3 = 0.000893, and A_4 = 0.003796.[13] These values were selected such that the projection yields unit scale along the equator (y(\theta = 0) = 0, \frac{dy}{d\theta}|_{\theta=0} = 1) and satisfies the equal-area differential condition \frac{d y}{d \varphi} = \sqrt{3} \cos \varphi / \cos \theta.[13] The resulting equations are computationally efficient, requiring no iterative solving for the forward map.[13]Projection Parameters and Computation
The Equal Earth projection employs a fixed set of parameters with no adjustable elements such as standard parallels, ensuring a consistent global mapping optimized for equal-area preservation and aesthetic balance.[13] The core computation introduces a parametric latitude θ derived directly from the geographic latitude φ via the relation \sin \theta = \frac{\sqrt{3}}{2} \sin \varphi, which rescales latitudes to facilitate pseudocylindrical symmetry while approximating spherical curvature.[13] This step is algebraic and non-iterative, yielding θ through the arcsine function. The projection's forward transformation from longitude λ and φ to Cartesian coordinates x and y (in radians, with the equator and prime meridian as axes) relies on four empirically fitted coefficients A_1 = 1.340264, A_2 = -0.081106, A_3 = 0.000893, and A_4 = 0.003796, selected via numerical optimization to minimize shape distortion in mid-latitudes and evoke the Robinson projection's visual familiarity under equal-area constraints.[13] These values ensure the y-coordinate follows a ninth-degree polynomial in θ for meridional spacing, while the x-coordinate incorporates a longitude-scaled term modulated by cosine of θ and normalized by the polynomial's derivative to enforce area conservation: The denominator in the x-equation represents the derivative of the y-polynomial with respect to θ, guaranteeing that areal scales remain proportional to \cos \varphi.[13] Computation is efficient, involving standard trigonometric and polynomial evaluations, with no iteration required for forward projection; scaling to specific map dimensions typically applies a constant factor to both x and y post-computation.[4] The inverse projection, converting x and y back to λ and φ, necessitates numerical iteration to solve the ninth-degree equation for θ given y, as no closed-form solution exists; methods such as Newton-Raphson convergence, initialized near y itself due to the function's near-linearity at low latitudes, typically require fewer than 10 iterations for double-precision accuracy.[13] Once θ is obtained, λ follows algebraically as \lambda = \frac{3x (9 A_4 \theta^8 + 7 A_3 \theta^6 + 3 A_2 \theta^2 + A_1)}{2 \sqrt{3} \cos \theta}, and φ from \sin \varphi = \frac{2}{\sqrt{3}} \sin \theta.[4] Implementations in libraries like PROJ incorporate safeguards for polar regions and convergence tolerances to handle edge cases.[4]Properties and Distortions
Equal-Area Preservation
The Equal Earth projection preserves the relative areas of all regions on the Earth's surface, ensuring that mapped features such as continents or countries appear in their correct proportional sizes without systematic enlargement or shrinkage.[2][3] This equal-area property is a defining characteristic, distinguishing it from non-equal-area projections like the Robinson, which prioritize shape over area fidelity.[4] Area preservation is mathematically ensured by formulating the projection such that the y-coordinate function equals the integral of the cosine of latitude weighted by the authalic radius factor, maintaining the differential area element dx dy equivalent to the spherical area R^2 cos φ dφ dλ, where R is Earth's radius, φ latitude, and λ longitude.[2] The developers prove this equivalence in the projection's appendix, confirming that the chosen polynomial approximation for the meridional coordinate satisfies the equal-area condition across all latitudes.[2] This property is visually verifiable using Tissot's indicatrix, where projected infinitesimal circles deform into ellipses of constant area throughout the map, demonstrating uniform area scale despite varying shape and angular distortions.[2] Consequently, the projection is particularly suited for thematic world maps illustrating phenomena like population density, land cover, or resource distribution, where accurate areal proportions are essential to avoid misleading interpretations of spatial data.[5][3]Shape, Distance, and Scale Distortions
The Equal Earth projection preserves areas globally but distorts shapes, distances, and local scales as a consequence of flattening the spherical surface onto a plane. Shapes of landmasses and other features appear relatively natural near the equator and in mid-latitudes, with continental outlines maintaining a balanced, globe-like curvature due to the projection's pseudocylindrical design and polynomial formulation for latitude. However, angular distortions increase toward the poles, where Tissot's indicatrices—ellipses representing projected infinitesimal circles—exhibit greater eccentricity, compressing features east-west relative to north-south dimensions.[14][15] Local scale factors vary systematically with latitude to enforce equal-area preservation, where the product of meridional and parallel scale factors equals unity everywhere. In tropical and mid-latitude zones, north-south scales are stretched, elongating features meridionally, while parallel scales contract accordingly; this results in scale distortion maxima around 40° latitude, with values exceeding 1.2 times the equatorial scale in some analyses. Near the poles, east-west scales compress significantly, approaching zero at the pole itself, though the projection avoids the infinite stretching seen in conformal projections like Mercator.[14][8] Distances are not preserved, with meridional distances overestimated in lower latitudes and underestimated poleward, reflecting the projection's emphasis on area over metric fidelity. For instance, great-circle distances along meridians deviate from true lengths by up to 20% in equatorial bands, decreasing toward higher latitudes where compression dominates. These patterns yield favorable overall distortion for thematic world mapping, outperforming elongated equal-area alternatives like the Gall–Peters in perceptual balance, though quantitative angular distortion metrics show maxima around 30–40° compared to optimized older pseudocylindrical forms.[14][15][8]Visual Characteristics Compared to Globe
The Equal Earth projection features curved pseudomeridians and a rounded outer graticule that visually evoke the spherical geometry of Earth, providing an overall outline more suggestive of a globe than the rectangular forms of many cylindrical projections.[5] Its pseudocylindrical design positions the equator as a straight line of reference, with parallels remaining straight but unequally spaced to contract toward the poles, facilitating straightforward latitudinal comparisons absent on a physical globe where parallels form concentric circles diminishing in circumference.[1] Continental landmasses, concentrated in tropical and mid-latitude bands, appear compact and balanced, with reduced elongation in regions like Africa compared to taller depictions in equal-area cylindrical alternatives, yielding shapes that are more recognizable and aesthetically harmonious relative to globe views.[5][16] In contrast to a globe's distortion-free preservation of local shapes, angles, and relative positions, the Equal Earth projection introduces areal fidelity at the expense of conformal accuracy, manifesting in angular distortions that increase toward the periphery and poles.[5] High-latitude features, such as Greenland or Antarctica, exhibit vertical compression—poles rendered as finite straight lines approximately 0.59 times the equator's projected length—resulting in a squished appearance that understates meridional extents unlike the globe's pinpoint polar convergence.[5] Tissot's indicatrix analysis reveals elliptical deformation patterns, with maximal shape distortion metrics around 2.0 in peripheral zones, prioritizing global area equivalence over the globe's isotropic representation.[5] ![Equal Earth projection with Tissot's indicatrices illustrating distortion patterns][center] This design choice yields a visually pleasing compromise for thematic world mapping, where the globe-like curvature and minimized mid-latitude warping enhance perceptual balance without the globe's three-dimensional fidelity or navigational precision.[1][16]Comparisons to Other Projections
Versus Compromise Projections like Robinson
The Equal Earth projection serves as an equal-area counterpart to compromise projections such as the Robinson, which prioritize visual balance over strict adherence to any single geometric property. Developed in 2018 by Bojan Šavrič, Bernhard Jenny, and Tom Patterson, Equal Earth emulates the Robinson's pseudocylindrical form, featuring curved meridians that arc outward to evoke the globe's sphericity and straight parallels for straightforward latitudinal comparisons, while the equator spans approximately 2.05 times the length of the central meridian and polar lines measure 0.59 times that equatorial span.[5] In contrast, the Robinson projection, introduced by Arthur H. Robinson in 1963, employs a table of precomputed values to approximate minimal overall distortion, resulting in a similar graticule outline but with meridians that bulge more excessively outward.[5] This design choice in Equal Earth yields continental shapes that appear less elongated in tropical zones and less flattened at the poles compared to traditional equal-area projections, achieving a comparable aesthetic appeal to Robinson without compromising area fidelity.[1] A primary distinction lies in area preservation: Equal Earth maintains exact equivalence, ensuring that regions like Africa retain their true proportional size relative to Greenland or Antarctica, whereas Robinson systematically enlarges high-latitude landmasses—such as making Greenland appear roughly 1.7 times larger than its actual area relative to Africa—due to its non-equal-area nature.[5] [1] This makes Equal Earth preferable for thematic cartography, including maps of population distribution, land use, or climate data, where misrepresented areas could skew quantitative interpretations; Robinson, by design, trades area accuracy for reduced shape and angular distortions in mid-latitudes, rendering it more suitable for general reference maps emphasizing recognizable outlines over metric precision.[5] Distortion analyses, such as those using Tissot's indicatrix, reveal that Equal Earth's area-correcting mechanism introduces moderate shape distortions akin to Robinson's balanced compromises, but with lower maximum angular deviations in equatorial and polar extremes, fostering a more uniform perceptual accuracy across the map.[17] Computationally, Equal Earth's analytical equations enable efficient rendering without Robinson's reliance on interpolation tables, facilitating broader implementation in geographic information systems while upholding the visual continuity that has sustained Robinson's popularity since its adoption by outlets like National Geographic in the 1980s.[5] However, for navigation or applications demanding conformal properties, neither projection excels, as both prioritize global over regional fidelity; Robinson's broader distortion spread may still appeal in scenarios where aesthetic familiarity outweighs area integrity, though Equal Earth's integration of globe-mimetic visuals with empirical accuracy positions it as a rigorous advancement for truth-oriented mapping.[17]Versus Other Equal-Area Projections like Gall-Peters
The Equal Earth projection and the Gall–Peters projection both belong to the class of equal-area map projections, preserving the relative sizes of landmasses and enabling accurate comparisons of areas such as population density or resource distribution.[2] However, their geometric constructions differ fundamentally: Gall–Peters employs a cylindrical framework with equally spaced meridians and parallels, which enforces a rectangular graticule but introduces severe shape distortions, particularly meridional elongation at higher latitudes where continents appear unnaturally stretched vertically.[1] In contrast, Equal Earth adopts a pseudocylindrical design with sinusoidally curved meridians that converge toward the poles, yielding an elliptical overall outline reminiscent of a globe and reducing these elongations by compressing longitudinal extents in polar regions.[2] This pseudocylindrical approach in Equal Earth results in more recognizable continental shapes compared to Gall–Peters, where, for instance, Africa and Eurasia retain proportions closer to their globular forms without the extreme north-south expansion seen in the latter.[1] Tissot's indicatrix analyses reveal that Equal Earth distributes angular distortions more evenly across the map, with maximal scale factors around 1.5 in equatorial belts tapering toward the poles, whereas Gall–Peters exhibits scale factors exceeding 2.0 in high latitudes, exacerbating angular infidelity.[18] The Equal Earth designers prioritized aesthetic balance alongside area preservation, drawing inspiration from compromise projections like Robinson to mitigate the "unappealing" visual artifacts of cylindrical equal-area maps, which Gall–Peters exemplifies despite its utility for thematic area-based mapping.[2][8] While Gall–Peters gained prominence in the 1970s and 1980s for emphasizing equatorial regions' true extents amid critiques of Mercator's biases, its shape compromises limited broader adoption in general cartography.[19] Equal Earth, introduced in 2018, addresses these by optimizing for both metric fidelity and perceptual accuracy, making it preferable for world maps where shape intuition aids interpretation without sacrificing areas—evident in its smoother convergence of poles and reduced boundary discontinuities relative to Gall–Peters' rigid grid.[2] Empirical tests by the projection's creators confirmed lower subjective distortion ratings for Equal Earth among cartographers evaluating landmark recognizability.[1]Versus Navigation-Focused Projections like Mercator
The Equal Earth projection prioritizes areal preservation over angular fidelity, rendering it unsuitable for navigational applications where the Mercator projection excels. Developed in 1569 by Gerardus Mercator specifically for sea charts, the Mercator projection maintains conformality, ensuring that angles between lines are preserved locally and rhumb lines—paths of constant compass bearing—appear as straight lines, which simplifies plotting courses for sailors maintaining fixed headings.[20] In contrast, the Equal Earth projection, formulated in 2018, introduces angular distortions that curve such lines, prioritizing instead the accurate depiction of relative areas for global thematic mapping.[19][13] Mercator's cylindrical design yields extreme areal inflation toward the poles, with scale factors diverging to infinity beyond approximately 85° latitude, causing high-latitude landmasses like Greenland to appear roughly 14 times their actual size relative to equatorial regions such as Africa.[21] This distortion, while negligible near the equator for short-distance navigation, misrepresents global proportions on world maps, fostering misconceptions about continental sizes. Equal Earth avoids such inflation through its pseudocylindrical equal-area framework, which constrains polar expansion and yields a more balanced continental outline resembling a globe's silhouette, though at the expense of moderate shape shearing in mid- to high latitudes.[22] Tissot's indicatrix analyses reveal Mercator's uniform angular preservation but radially expanding area ellipses at higher latitudes, versus Equal Earth's area-constant circles that elongate into ellipses with varying orientations, underscoring the trade-off: Mercator favors local shape accuracy for directional tasks, while Equal Earth supports quantitative areal comparisons essential for data visualization, such as population density or resource distribution.[22] For web mapping, variants like Web Mercator inherit these issues but enable efficient tiling due to their rectangular grid, though they amplify distortions for global views; Equal Earth, implemented in tools like ArcGIS since around 2019, better serves static world references without navigational intent.[21]Adoption and Applications
Implementation in Software and Standards
The Equal Earth projection is implemented in the PROJ library, a widely used open-source cartographic projections and coordinate transformations package, with support added in version 6.0 released in 2018.[4] PROJ's implementation enables its use in numerous GIS applications that rely on the library for projection handling.[4] In commercial GIS software, ArcGIS Pro and ArcGIS Desktop include native support for Equal Earth as an equal-area pseudocylindrical projection suitable for world maps, with parameters configured for global extents.[3][14] Open-source alternatives like QGIS support it through custom projection definitions using the PROJ4 string+proj=eqearth +wktext, allowing users to define it via settings menus or project files since at least version 3.0.[23][24]
Programming libraries facilitate broader adoption: Python's Cartopy and GeoPandas integrate it via PROJ, while matplotlib offers a dedicated EqualEarth class for static mapping.[25][26] In R, the sf package accesses it through PROJ integration, enabling spatial data transformations.[27] Additional tools such as NASA's G.Projector, NOAA's Panoply, and Flex Projector provide built-in Equal Earth options for visualization and experimentation.[5]
For standards, the projection is codified as EPSG:8857 in the European Petroleum Survey Group (EPSG) registry, defining its parameters for interoperability in geospatial data exchange and defining a geographic CRS based on WGS 84 with units in meters.[28] JavaScript implementations are available for web mapping, downloadable from project repositories for direct integration into libraries like D3.js.[1] These implementations emphasize computational efficiency due to the projection's simple polynomial equations.[29]