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A hyperbola consists of all points where the absolute difference of distances to two fixed points, called foci, remains constant. The standard equation isEach branch extends infinitely and approaches two asymptotes, which guide the curve’s behavior. The parameters a and b define key features: a measures the distance from the center to each vertex along the transverse axis, while b influences the slopes of the asymptotes. The asymptotes have equationsA rectangle centered at the origin with...
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A hyperbola is a conic section produced when a double-napped cone is intersected by a plane at an angle steeper than the slope of the cone, such that it cuts through both nappes. This intersection yields two separate, mirror-image curves known as branches, which open away from each other along the transverse axis. The nearest points on each branch to the hyperbola’s center are termed vertices, and the distance from the center to a vertex is denoted by a. Perpendicular to the transverse...
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The polar coordinate system represents points using a distance from a central point (the pole) and an angle from a reference direction (the polar axis). Unlike rectangular coordinates, polar coordinates are ideal for graphing curves with radial symmetry or periodic behavior.Some general forms of graphs in polar coordinates include the following:Equation of a Circle (Centered at the Pole):A graph where the radius remains constant for all angles traces a circle centered at the pole:Equation of a...
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A planar symmetry of charge density is obtained when charges are uniformly spread over a large flat surface. In planar symmetry, all points in a plane parallel to the plane of charge are identical with respect to the charges. Suppose the plane of the charge distribution is the xy-plane, and the electric field at a space point P with coordinates (x, y, z) is to be determined. Since the charge density is the same at all (x, y) - coordinates in the z = 0 plane, by symmetry, the electric field at P...
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Graphs of functions provide a visual representation of how output values change in response to varying inputs. Each point on the graph corresponds to an ordered pair, where the x-coordinate (independent variable) determines the horizontal position and the y-coordinate (dependent variable) determines the vertical position. Linear functions like y = x give a straight line, indicating a constant rate of change.Nonlinear functions display more complex behaviors. Even power functions generate...
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An equation with two variables, typically written in the form y = f(x) or Ax + By = C, describes a relationship between quantities represented by x and y. Each solution to such an equation is an ordered pair (x, y) that satisfies the equation when substituted. These pairs can be represented graphically to understand the variables' relationship visually.A common technique for constructing the graph of a two-variable equation is to create a value table. Begin by choosing several values for the...
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Random hyperbolic graphs with arbitrary mesoscale structures.

Stefano Guarino1, Enrico Mastrostefano1, Davide Torre2

  • 1Istituto per le Applicazioni del Calcolo "Mauro Picone" (CNR-IAC), Via dei Taurini 19, Rome 00185, Italy.

Physical Review. E
|December 23, 2025
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Summary
This summary is machine-generated.

We introduce the random hyperbolic block model (RHBM) to better capture community structures in real-world networks. This model extends random hyperbolic graphs by incorporating block structures, overcoming limitations of purely geometric approaches.

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Area of Science:

  • Network Science
  • Complex Systems
  • Graph Theory

Background:

  • Real-world networks exhibit universal properties like sparsity, small-worldness, and community structures.
  • Geometric network models, such as random hyperbolic graphs (RHGs), capture many network features by embedding nodes in a latent similarity space.
  • However, purely geometric models struggle to represent non-geometric community structures where inter-group dissimilarity violates the triangle inequality.

Purpose of the Study:

  • To address the limitations of existing geometric network models in capturing mesoscale community structures.
  • To introduce a novel network model that incorporates block structures while retaining latent geometry.
  • To enhance the ability of network models to represent diverse real-world network topologies.

Main Methods:

  • Introduction of the random hyperbolic block model (RHBM), extending RHGs with block structures.
  • Utilizing a maximum-entropy framework to incorporate community structures into the model.
  • Analysis of synthetic networks to demonstrate the capabilities of RHBM.

Main Results:

  • RHBM effectively preserves community structures, outperforming purely geometric models in this aspect.
  • The model demonstrates flexibility in generating networks with specific mesoscale mixing patterns.
  • Synthetic network analyses validate the advantages of RHBM in capturing non-geometric community features.

Conclusions:

  • The random hyperbolic block model (RHBM) offers a significant advancement in modeling complex networks with community structures.
  • RHBM highlights the importance of latent geometry while addressing its limitations in controlling mesoscale organization.
  • This model provides a more accurate representation of real-world networks characterized by both geometric and block properties.