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=== Barbell Graph === Info * Returns a barbell graph with 2*n1 + n2 nodes. n1 must be greater than or equal to 2. * A barbell graph is a basic structure that consists of a path graph of order n2 connecting two complete graphs of order n1 each. * This constructor depends on NetworkX numeric labels. In this case, the (n1)th node connects to the path graph from one complete graph and the (n1+n2+1)th node connects to the path graph from the other complete graph. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each barbell graph will be displayed with the two complete graphs in the lower-left and upper-right corners, with the path graph connecting diagonally between the two. Thus the (n1)th node will be drawn at a 45 degree angle from the horizontal right center of the first complete graph, and the (n1+n2+1)th node will be drawn 45 degrees below the left horizontal center of the second complete graph. Code {{{ pos_dict = {} for i in range(n1): x = float(cos((pi/4) - ((2*pi)/n1)*i) - n2/2 - 1) y = float(sin((pi/4) - ((2*pi)/n1)*i) - n2/2 - 1) j = n1-1-i pos_dict[j] = [x,y] for i in range(n1+n2)[n1:]: x = float(i - n1 - n2/2 + 1) y = float(i - n1 - n2/2 + 1) pos_dict[i] = [x,y] for i in range(2*n1+n2)[n1+n2:]: x = float(cos((5*pi/4) + ((2*pi)/n1)*(i-n1-n2)) + n2/2 + 2) y = float(sin((5*pi/4) + ((2*pi)/n1)*(i-n1-n2)) + n2/2 + 2) pos_dict[i] = [x,y] import networkx G = networkx.barbell_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="Barbell graph") }}} ==== Examples ==== {{{ # Construct and show a barbell graph # Bar = 4, Bells = 9 sage: g = graphs.BarbellGraph(9,4) sage: g.show() }}} attachment here === Bull Graph === Info * Returns a bull graph with 5 nodes. * A bull graph is named for its shape. It's a triangle with horns. * This constructor depends on NetworkX numeric labeling. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the bull graph is drawn as a triangle with the first node (0) on the bottom. The second and third nodes (1 and 2) complete the triangle. Node 3 is the horn connected to 1 and node 4 is the horn connected to node 2. Code {{{ pos_dict = [[0,0],[-1,1],[1,1],[-2,2],[2,2]] import networkx G = networkx.bull_graph() return graph.Graph(G, pos=pos_dict, name="Bull Graph") }}} ==== Examples ==== {{{ # Construct and show a bull graph sage: g = graphs.BullGraph() sage: g.show() }}} attachment here === Circular Ladder Graph === Info * Returns a circular ladder graph with 2*n nodes. * A Circular ladder graph is a ladder graph that is connected at the ends, i.e.: a ladder bent around so that top meets bottom. Thus it can be described as two parrallel cycle graphs connected at each corresponding node pair. * This constructor depends on NetworkX numeric labels. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the circular ladder graph is displayed as an inner and outer cycle pair, with the first n nodes drawn on the inner circle. The first (0) node is drawn at the top of the inner-circle, moving clockwise after that. The outer circle is drawn with the (n+1)th node at the top, then counterclockwise as well. Code {{{ pos_dict = {} for i in range(n): x = float(cos((pi/2) + ((2*pi)/n)*i)) y = float(sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] for i in range(2*n)[n:]: x = float(2*(cos((pi/2) + ((2*pi)/n)*(i-n)))) y = float(2*(sin((pi/2) + ((2*pi)/n)*(i-n)))) pos_dict[i] = [x,y] import networkx G = networkx.circular_ladder_graph(n) return graph.Graph(G, pos=pos_dict, name="Circular Ladder graph") }}} ==== Examples ==== {{{ # Construct and show a circular ladder graph with 26 nodes sage: g = graphs.CircularLadderGraph(13) sage: g.show() }}} attachment here {{{ # Create several circular ladder graphs in a SAGE graphics array sage: g = [] sage: j = [] sage: for i in range(9): ... k = graphs.CircularLadderGraph(i+3) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment here |
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import networkx as NX | |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) |
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=== Diamond Graph === Info * Returns a diamond graph with 4 nodes. * A diamond graph is a square with one pair of diagonal nodes connected. * This constructor depends on NetworkX numeric labeling. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the diamond graph is drawn as a diamond, with the first node on top, second on the left, third on the right, and fourth on the bottom; with the second and third node connected. Code {{{ pos_dict = [[0,1],[-1,0],[1,0],[0,-1]] import networkx G = networkx.diamond_graph() return graph.Graph(G, pos=pos_dict, name="Diamond Graph") }}} ==== Examples ==== {{{ # Construct and show a diamond graph sage: g = graphs.DiamondGraph() sage: g.show() }}} attachment here |
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=== Grid2d Graphs === Info * Returns a 2-dimensional grid graph with n1*n2 nodes (n1 rows and n2 columns). * A 2d grid graph resembles a 2 dimensional grid. All inner nodes are connected to their 4 neighbors. Outer (non-corner) nodes are connected to their 3 neighbors. Corner nodes are connected to their 2 neighbors. * This constructor depends on NetworkX numeric labels. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, nodes are labelled in (row, column) pairs with (0, 0) in the top left corner. Edges will always be horizontal and vertical - another advantage of filling the position dictionary. Code {{{ pos_dict = {} for i in range(n1): y = -i for j in range(n2): x = j pos_dict[i,j] = [x,y] import networkx G = networkx.grid_2d_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="2D Grid Graph") }}} ==== Examples ==== {{{ # Construct and show a grid 2d graph # Rows = 5, Columns = 7 sage: g = graphs.Grid2dGraph(5,7) sage: g.show() }}} attachment here === House Graph === Info * Returns a house graph with 5 nodes. * A house graph is named for its shape. It is a triange (roof) over a square (walls). * This constructor depends on NetworkX numeric labeling. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the house graph is drawn with the first node in the lower-left corner of the house, the second in the lower-right corner of the house. The third node is in the upper-left corner connecting the roof to the wall, and the fourth is in the upper-right corner connecting the roof to the walll. The fifth node is the top of the roof, connected only to the third and fourth. Code ==== This has been updated! Change! ==== {{{ pos_dict = [[-1,0],[1,0],[-1,1],[1,1],[0,2]] import networkx G = networkx.house_graph() return graph.Graph(G, pos=pos_dict, name="House Graph") ==== Examples ==== {{{ # Construct and show a house graph sage: g = graphs.HouseGraph() sage: g.show() }}} attachment here === House X Graph === Info * Returns a house X graph with 5 nodes. * A house X graph is a house graph with two additional edges. The upper-right corner is connected to the lower-left. And the upper-left corner is connected to the lower-right. * This constructor depends on NetworkX numeric labeling. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the house X graph is drawn with the first node in the lower-left corner of the house, the second in the lower-right corner of the house. The third node is in the upper-left corner connecting the roof to the wall, and the fourth is in the upper-right corner connecting the roof to the walll. The fifth node is the top of the roof, connected only to the third and fourth. ==== Code, has been updated! ==== {{{ pos_dict = [[-1,0],[1,0],[-1,1],[1,1],[0,2]] import networkx G = networkx.house_x_graph() return graph.Graph(G, pos=pos_dict, name="House Graph") }}} ==== Examples ==== {{{ # Construct and show a house X graph sage: g = graphs.HouseXGraph() sage.: g.show() }}} attachment here === Krackhardt Kite Graph === Info * Returns a Krackhardt kite graph with 10 nodes. * This constructor depends on NetworkX numeric labeling. * The Krackhardt kite graph was originally developed by David Krackhardt for the purpose of studying social networks. It is used to show the distinction between: degree centrality, betweeness centrality, and closeness centrality. For more information read the plotting section below in conjunction with the example. References * Kreps, V. (2002). "Social Network Analysis". [http://www.fsu.edu/~spap/water/network/intro.htm Link] Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the graph is drawn left to right, in top to bottom row sequence of [2, 3, 2, 1, 1, 1] nodes on each row. This places the fourth node (3) in the center of the kite, with the highest degree. * But the fourth node only connects nodes that are otherwise connected, or those in its clique (i.e.: Degree Centrality). * The eigth (7) node is where the kite meets the tail. It has degree = 3, less than the average, but is the only connection between the kite and tail (i.e.: Betweenness Centrality). * The sixth and seventh nodes (5 and 6) are drawn in the third row and have degree = 5. These nodes have the shortest path to all other nodes in the graph (i.e.: Closeness Centrality). Please execute the example for visualization. Code {{{ pos_dict = [[-1,4],[1,4],[-2,3],[0,3],[2,3],[-1,2],[1,2],[0,1],[0,0],[0,-1]] import networkx G = networkx.krackhardt_kite_graph() return graph.Graph(G, pos=pos_dict, name="Krackhardt Kite Graph") }}} ==== Examples ==== {{{ # Construct and show a Krackhardt kite graph sage: g = graphs.KrackhardtKiteGraph() sage.: g.show() }}} attachment here === Ladder Graph === ---- /!\ '''Edit conflict - your version:''' ---- {{{ # Construct and show a house X graph sage: g = graphs.HouseXGraph() sage.: g.show() }}} attachment here === Krackhardt Kite Graph === Info * Returns a Krackhardt kite graph with 10 nodes. * This constructor depends on NetworkX numeric labeling. * The Krackhardt kite graph was originally developed by David Krackhardt for the purpose of studying social networks. It is used to show the distinction between: degree centrality, betweeness centrality, and closeness centrality. For more information read the plotting section below in conjunction with the example. References * Kreps, V. (2002). "Social Network Analysis". [http://www.fsu.edu/~spap/water/network/intro.htm Link] Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the graph is drawn left to right, in top to bottom row sequence of [2, 3, 2, 1, 1, 1] nodes on each row. This places the fourth node (3) in the center of the kite, with the highest degree. * But the fourth node only connects nodes that are otherwise connected, or those in its clique (i.e.: Degree Centrality). * The eigth (7) node is where the kite meets the tail. It has degree = 3, less than the average, but is the only connection between the kite and tail (i.e.: Betweenness Centrality). * The sixth and seventh nodes (5 and 6) are drawn in the third row and have degree = 5. These nodes have the shortest path to all other nodes in the graph (i.e.: Closeness Centrality). Please execute the example for visualization. Code {{{ pos_dict = [[-1,4],[1,4],[-2,3],[0,3],[2,3],[-1,2],[1,2],[0,1],[0,0],[0,-1]] import networkx G = networkx.krackhardt_kite_graph() return graph.Graph(G, pos=pos_dict, name="Krackhardt Kite Graph") }}} ==== Examples ==== {{{ # Construct and show a Krackhardt kite graph sage: g = graphs.KrackhardtKiteGraph() sage.: g.show() }}} attachment here === Ladder Graph === === Lollipop Graph === === Path Graph === |
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{{{ |
{{{ import networkx as NX |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
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... spr = NX.star_graph(i+3) | ... spr = NX.star_graph(i+3) |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
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pos_dict = {} pos_dict[0] = [0,0] for i in range(n)[1:]: x = float(functions.cos((pi/2) + ((2*pi)/(n-1))*(i-1))) y = float(functions.sin((pi/2) + ((2*pi)/(n-1))*(i-1))) pos_dict[i] = [x,y] G = NX.wheel_graph(n) return graph.Graph(G, pos=pos_dict, name="Wheel graph on %d vertices"%n) |
import networkx as NX pos_dict = {} pos_dict[0] = [0,0] for i in range(n)[1:]: x = float(functions.cos((pi/2) + ((2*pi)/(n-1))*(i-1))) y = float(functions.sin((pi/2) + ((2*pi)/(n-1))*(i-1))) pos_dict[i] = [x,y] G = NX.wheel_graph(n) return graph.Graph(G, pos=pos_dict, name="Wheel graph on %d vertices"%n) |
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CPU time: 0.07 s, Wall time: 0.09 s[[br]] (Time results will vary._ | CPU time: 0.07 s, Wall time: 0.09 s[[br]] (Time results will vary.) |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
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import networkx as NX | |
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Petersen Graph as constructed in this class: {{{ sage: petersen_database = graphs.PetersenGraph() sage: petersen_database.show() }}} attachment:petersen_pos.png Petersen Graph plotted using the spring layout algorithm: {{{ sage: petersen_spring = Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9],\ 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]}) sage: petersen_spring.show() }}} attachment:petersen_spring.png == Graph Families == === Complete Graphs === Info * Returns a complete graph on n nodes. * A Complete Graph is a graph in which all nodes are connected to all other nodes. * This constructor is dependant on vertices numbered 0 through n-1 in NetworkX complete_graph() Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete graph will be displayed with the first (0) node at the top, with the rest following in a counterclockwise manner. * In the complete graph, there is a big difference visually in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph, making it clear which nodes an edge is connected to. But the complete graph offers a good example of how the spring-layout works. The edges push outward (everything is connected), causing the graph to appear as a 3-dimensional pointy ball. (See examples below). * Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code. Code {{{ import networkx as NX pos_dict = {} for i in range(n): x = float(functions.cos((pi/2) + ((2*pi)/n)*i)) y = float(functions.sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] G = NX.complete_graph(n) return graph.Graph(G, pos=pos_dict, name="Complete graph on %d vertices"%n) ---- /!\ '''End of edit conflict''' ---- }}} ==== Examples ==== ---- /!\ '''Edit conflict - other version:''' ---- |
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{{{ sage: g = [] sage: j = [] |
---- /!\ '''Edit conflict - your version:''' ---- The following examples require NetworkX (to use default): {{{ sage: import networkx as NX }}} Compare the constructor speeds. {{{ time n = NX.complete_graph(1559); spring1559 = Graph(n) }}} CPU time: 6.85 s, Wall time: 9.71 s[[BR]](Time results vary.) {{{ time posdict1559 = graphs.CompleteGraph(1559) }}} CPU time: 9.67 s, Wall time: 11.75 s[[BR]](Time results vary.) Compare the plotting speeds. {{{ sage: n = NX.complete_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.CompleteGraph(23) }}} {{{ time spring23.show() }}} CPU time: 3.51 s, Wall time: 4.29 s[[BR]](Time Results will vary.) attachment:complete_spr23.png {{{ time posdict23.show() }}} CPU time: 0.82 s, Wall time: 0.96 s[[BR]](Time Results will vary.) attachment:complete_pd23.png View many Complete graphs as a SAGE Graphics Array. With the position dictionary filled: ---- /!\ '''End of edit conflict''' ---- {{{ sage: g = [] sage: j = [] ---- /!\ '''Edit conflict - other version:''' ---- |
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... n.append(g[3*i + m].plot(node_size=50, with_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} |
... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ---- /!\ '''Edit conflict - your version:''' ---- sage: for i in range(9): ... k = graphs.CompleteGraph(i+3) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ---- /!\ '''End of edit conflict''' ---- ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} ---- /!\ '''Edit conflict - other version:''' ---- |
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... n.append(g[3*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) |
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... n.append(g[3*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) |
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... n.append(g[3*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) |
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... n.append(g[4*i + m].plot(node_size=50, with_labels=False)) | ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) |
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---- /!\ '''Edit conflict - your version:''' ---- attachment:complete_array_pd.png With the spring-layout algorithm: {{{ sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment:complete_array_spr.png === Complete Bipartite Graphs === Info * Returns a Complete Bipartite Graph sized n1+n2, with each of the nodes [0,(n1-1)] connected to each of the nodes [n1,(n2-1)] and vice versa. * A Complete Bipartite Graph is a graph with its vertices partitioned into two groups, V1 and V2. Each v in V1 is connected to every v in V2, and vice versa. Plotting * Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete bipartite graph will be displayed with the first n1 nodes on the top row (at y=1) from left to right. The remaining n2 nodes appear at y=0, also from left to right. The shorter row (partition with fewer nodes) is stretched to the same length as the longer row, unless the shorter row has 1 node; in which case it is centered. The x values in the plot are in domain [0,max{n1,n2}]. * In the Complete Bipartite graph, there is a visual difference in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph and separates the partitioned nodes, making it clear which nodes an edge is connected to. The Complete Bipartite graph plotted with the spring-layout algorithm tends to center the nodes in n1 (see spring_med in examples below), thus overlapping its nodes and edges, making it typically hard to decipher. * Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code. Code {{{ pos_dict = {} c1 = 1 # scaling factor for top row c2 = 1 # scaling factor for bottom row c3 = 0 # pad to center if top row has 1 node c4 = 0 # pad to center if bottom row has 1 node if n1 > n2: if n2 == 1: c4 = (n1-1)/2 else: c2 = ((n1-1)/(n2-1)) elif n2 > n1: if n1 == 1: c3 = (n2-1)/2 else: c1 = ((n2-1)/(n1-1)) for i in range(n1): x = c1*i + c3 y = 1 pos_dict[i] = [x,y] for i in range(n1+n2)[n1:]: x = c2*(i-n1) + c4 y = 0 pos_dict[i] = [x,y] G = NX.complete_bipartite_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="Complete bipartite graph on %d vertices"%(n1+n2)) }}} ==== Examples ==== The following examples require NetworkX (to use default): {{{ sage: import networkx as NX }}} Compare the constructor speeds. {{{ time n = NX.complete_bipartite_graph(389,157); spring_big = Graph(n) }}} CPU time: 9.28 s, Wall time: 11.02 s[[BR]](Time results will vary.) {{{ time posdict_big = graphs.CompleteBipartiteGraph(389,157) }}} CPU time: 10.72 s, Wall time: 13.84 s[[BR]](Time results will vary.) Compare the plotting speeds. {{{ sage: n = NX.complete_bipartite_graph(11,17) sage: spring_med = Graph(n) sage: posdict_med = graphs.CompleteBipartiteGraph(11,17) }}} {{{ time spring_med.show() }}} CPU time: 3.84 s, Wall time: 4.49 s[[BR]](Time results will vary.) attachment:compbip_spr_med.png {{{ time posdict_med.show() }}} CPU time: 0.96 s, Wall time: 1.14 s[[BR]](Time results will vary.) attachment:compbip_pd_med.png View many Complete Bipartite graphs as a SAGE Graphics Array. With the position dictionary filled: {{{ sage: g = [] sage: j = [] sage: for i in range(9): ... k = graphs.CompleteBipartiteGraph(i+1,4) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment:compbip_array_pd.png With the spring-layout algorithm: {{{ sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_bipartite_graph(i+1,4) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment:compbip_array.spr.png == Random Graph Generators == === RandomGNP === Info * Returns a Random graph on n nodes. Each edge is inserted independently with probability p. * If p is small, use RandomGNPFast. See NetworkX documentation. C.f. P. Erdos and A. Renyi, On Random Graphs, Publ. Math. 6, 290 (1959). E. N. Gilbert, Random Graphs, Ann. Math. Stat., 30, 1141 (1959). Plotting * When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified. Code {{{ import networkx as NX G = NX.gnp_random_graph(n, p, seed) return graph.Graph(G) }}} ==== Examples ==== Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs {{{ time regular_sparse = graphs.RandomGNP(1559,.22) }}} CPU time: 31.79 s, Wall time: 38.78 s[[BR]](Time results will vary.) {{{ time fast_sparse = graphs.RandomGNPFast(1559,.22) }}} CPU time: 21.72 s, Wall time: 26.44 s[[BR]](Time results will vary.) Dense Graphs {{{ time regular_dense = graphs.RandomGNP(1559,.88) }}} CPU time: 38.75 s, Wall time: 47.65 s[[BR]](Time results will vary.) {{{ time fast_dense = graphs.RandomGNP(1559,.88) }}} CPU time: 39.15 s, Wall time: 48.22 s[[BR]](Time results will vary.) Plot a random graph on 12 nodes with p = .71 {{{ sage: gnp = graphs.RandomGNP(12,.71) sage: gnp.show() }}} attachment:rand_reg.png View many random graphs using a SAGE Graphics Array {{{ sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNP(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment:rand_array_reg.png === RandomGNPFast === Info * Returns a Random graph on n nodes. Each edge is inserted independently with probability p. * Use for small p (sparse graphs). See NetworkX documentation. Plotting * When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified. Code {{{ import networkx as NX G = NX.fast_gnp_random_graph(n, p, seed) return graph.Graph(G) }}} ==== Examples ==== Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs {{{ time regular_sparse = graphs.RandomGNP(1559,.22) }}} CPU time: 31.79 s, Wall time: 38.78 s[[BR]](Time results will vary.) {{{ time fast_sparse = graphs.RandomGNPFast(1559,.22) }}} CPU time: 21.72 s, Wall time: 26.44 s[[BR]](Time results will vary.) Dense Graphs {{{ time regular_dense = graphs.RandomGNP(1559,.88) }}} CPU time: 38.75 s, Wall time: 47.65 s[[BR]](Time results will vary.) {{{ time fast_dense = graphs.RandomGNP(1559,.88) }}} CPU time: 39.15 s, Wall time: 48.22 s[[BR]](Time results will vary.) Plot a random graph on 12 nodes with p = .71 {{{ sage: fast = graphs.RandomGNPFast(12,.71) sage: fast.show() }}} attachment:rand_fast.png View many random graphs using a SAGE Graphics Array {{{ sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNPFast(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show() }}} attachment:rand_array_fast.png ---- /!\ '''End of edit conflict''' ---- |
The SAGE [http://sage.math.washington.edu:9001/graph Graph Theory Project] aims to implement Graph objects and algorithms in ["SAGE"].
The goal of the Graph Database is to implement constructors for many common graphs, as well as thorough docstrings that can be used for reference. The Graph Database will grow as the Graph Theory Project does. Robert Miller has been working on a graphics primitive for SAGE Graph objects, which has allowed us to pre-set a position dictionary for the x-y coordinates of each node. (Browse code and examples below). We also have the ability to view graphs in a SAGE Graphics Array, write text on the graphs, etc. that we inherit from having an associated SAGE Graphics Object for each SAGE Graph.
As we implement algorithms into the Graph Theory Package, the constructors of known graphs would set their properties upon instantiation as well. For example, if someone created a very large complete bipartite graph and then asked if it is a bipartite graph (not currently implemented), then instead of running through an algorithm to check it, we could return a value set at instantiation. Further, this will improve the reference use of the docstrings as we would list the properties of each named graph.
I am also launching a [http://sage.math.washington.edu:9001/graph_db_survey survey] of existing graph database software. I am looking for a substantially large database of graphs and their properties, so that users can query properties.
Scroll down to see current status and examples. There are lots of pictures, so I recommend using the Table of Contents to navigate. Also, please note the suggestions section. Posting suggestions there will be easiest for me to keep on top of.
Emily Kirkman is working on this project.
Suggestions
- ???
Graphs I Plan to Add
Recently Added: Info Coming Soon
- Barbell
- Circular ladder
- 2d Grid
- Ladder
- Lollipop
- Path
- Bull
- Diamond
- Dodecahedral
- House
- House x
- Icosahedral
- Krackhardt
- Octahedral
- Tetrahedral
- Cubes
Inherited from NetworkX
- Bipartite Generators
- Balanced tree
- Dorogovstev golstev mendes graph
- Grid (n-dim)
- Hypercube
- Chvatal
- Desargues
- Frucht
- Heawood
- Moebius kantor
- Pappus
- Sedgewick
- Truncated cube
- Truncated tetrahedron
- Tutte
- Also many more random generators and gens from degree sequence to sort through
Families of Graphs
- Generalized Petersen graphs
- Petersen Graph family
- Trees (Directed – not simple. Maybe Balanced tree constructor and query isTree)
- Cayley (Requires Edge Coloring)
- Paley
Named Graphs
- Thomsen
- Brinkman
- Clebsch
- Flower snark
- Icosahedron
- Grötzsch graph
- Tutte eight-cage
- Heawood graph
- Szekeres snark
- Thomassen graph
- Johnson (maybe own class)
- Turan
Currently Implemented in Graph Database
Class Docstrings
A collection of constructors of common graphs. USES: A list of all graphs and graph structures in this database is available via tab completion. Type "graphs." and then hit tab to see which graphs are available. The docstrings include educational information about each named graph with the hopes that this database can be used as a reference. PLOTTING: All graphs (i.e., networks) have an associated SAGE graphics object, which you can display: sage: G = WheelGraph(15) sage: p = G.plot() sage: is_Graphics(p) True When creating a graph in SAGE, the default positioning of nodes is determined using the spring-layout algorithm. Often, it is more efficient to pre-set the positions in a dictionary. Additionally, we can use this position dictionary to display the graph in an intuitive manner, whereas the spring-layout would fail if the graph is not very symmetric. For example, consider the Petersen graph with default node positioning vs. the Petersen graph constructed by this database: sage: petersen_spring = Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9],\ 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]}) sage.: petersen_spring.show() sage: petersen_database = graphs.PetersenGraph() sage.: petersen_database.show() For all the constructors in this database (except the random and empty graphs), the position dictionary is filled, instead of using the spring-layout algorithm. ORGANIZATION: The constructors available in this database are organized as follows: Basic Structures: - EmptyGraph - CycleGraph - StarGraph - WheelGraph Named Graphs: - PetersenGraph Families of Graphs: - CompleteGraph - CompleteBipartiteGraph - RandomGNP - RandomGNPFast AUTHORS: -- Robert Miller (2006-11-05): initial version - empty, random, petersen -- Emily Kirkman (2006-11-12): basic structures, node positioning for all constructors -- Emily Kirkman (2006-11-19): docstrings, examples TODO: [] more named graphs [] thorough docstrings and examples [] set properties (as they are implemented) [] add query functionality for large database
Basic Structures
Barbell Graph
Info
- Returns a barbell graph with 2*n1 + n2 nodes. n1 must be greater than or equal to 2.
- A barbell graph is a basic structure that consists of a path graph of order n2 connecting two complete graphs of order n1 each.
- This constructor depends on NetworkX numeric labels. In this case, the (n1)th node connects to the path graph from one complete graph and the (n1+n2+1)th node connects to the path graph from the other complete graph.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each barbell graph will be displayed with the two complete graphs in the lower-left and upper-right corners, with the path graph connecting diagonally between the two. Thus the (n1)th node will be drawn at a 45 degree angle from the horizontal right center of the first complete graph, and the (n1+n2+1)th node will be drawn 45 degrees below the left horizontal center of the second complete graph.
Code
pos_dict = {} for i in range(n1): x = float(cos((pi/4) - ((2*pi)/n1)*i) - n2/2 - 1) y = float(sin((pi/4) - ((2*pi)/n1)*i) - n2/2 - 1) j = n1-1-i pos_dict[j] = [x,y] for i in range(n1+n2)[n1:]: x = float(i - n1 - n2/2 + 1) y = float(i - n1 - n2/2 + 1) pos_dict[i] = [x,y] for i in range(2*n1+n2)[n1+n2:]: x = float(cos((5*pi/4) + ((2*pi)/n1)*(i-n1-n2)) + n2/2 + 2) y = float(sin((5*pi/4) + ((2*pi)/n1)*(i-n1-n2)) + n2/2 + 2) pos_dict[i] = [x,y] import networkx G = networkx.barbell_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="Barbell graph")
Examples
# Construct and show a barbell graph # Bar = 4, Bells = 9 sage: g = graphs.BarbellGraph(9,4) sage: g.show()
attachment here
Bull Graph
Info
- Returns a bull graph with 5 nodes.
- A bull graph is named for its shape. It's a triangle with horns.
- This constructor depends on NetworkX numeric labeling.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the bull graph is drawn as a triangle with the first node (0) on the bottom. The second and third nodes (1 and 2) complete the triangle. Node 3 is the horn connected to 1 and node 4 is the horn connected to node 2.
Code
pos_dict = [[0,0],[-1,1],[1,1],[-2,2],[2,2]] import networkx G = networkx.bull_graph() return graph.Graph(G, pos=pos_dict, name="Bull Graph")
Examples
# Construct and show a bull graph sage: g = graphs.BullGraph() sage: g.show()
attachment here
Circular Ladder Graph
Info
- Returns a circular ladder graph with 2*n nodes.
- A Circular ladder graph is a ladder graph that is connected at the ends, i.e.: a ladder bent around so that top meets bottom. Thus it can be described as two parrallel cycle graphs connected at each corresponding node pair.
- This constructor depends on NetworkX numeric labels.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the circular ladder graph is displayed as an inner and outer cycle pair, with the first n nodes drawn on the inner circle. The first (0) node is drawn at the top of the inner-circle, moving clockwise after that. The outer circle is drawn with the (n+1)th node at the top, then counterclockwise as well.
Code
pos_dict = {} for i in range(n): x = float(cos((pi/2) + ((2*pi)/n)*i)) y = float(sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] for i in range(2*n)[n:]: x = float(2*(cos((pi/2) + ((2*pi)/n)*(i-n)))) y = float(2*(sin((pi/2) + ((2*pi)/n)*(i-n)))) pos_dict[i] = [x,y] import networkx G = networkx.circular_ladder_graph(n) return graph.Graph(G, pos=pos_dict, name="Circular Ladder graph")
Examples
# Construct and show a circular ladder graph with 26 nodes sage: g = graphs.CircularLadderGraph(13) sage: g.show()
attachment here
# Create several circular ladder graphs in a SAGE graphics array sage: g = [] sage: j = [] sage: for i in range(9): ... k = graphs.CircularLadderGraph(i+3) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment here
Cycle Graphs
Info
- Returns a cycle graph with n nodes.
- A cycle graph is a basic structure which is also typically called an n-gon.
- This constructor is dependant on vertices numbered 0 through n-1 in NetworkX cycle_graph()
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each cycle graph will be displayed with the first (0) node at the top, with the rest following in a counterclockwise manner.
- The cycle graph is a good opportunity to compare efficiency of filling a position dictionary vs. using the spring-layout algorithm for plotting. Because the cycle graph is very symmetric, the resulting plots should be similar (in cases of small n).
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
import networkx as NX pos_dict = {} for i in range(n): x = float(functions.cos((pi/2) + ((2*pi)/n)*i)) y = float(functions.sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] G = NX.cycle_graph(n) return graph.Graph(G, pos=pos_dict, name="Cycle graph on %d vertices"%n)
Examples
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.cycle_graph(3989); spring3989 = Graph(n)
CPU time: 0.05 s, Wall time: 0.07 sBR (Time results will vary.)
time posdict3989 = graphs.CycleGraph(3989)
CPU time: 5.18 s, Wall time: 6.17 sBR (Time results will vary.)
Compare the plotting speeds.
sage: n = NX.cycle_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.CycleGraph(23)
time spring23.show()
CPU time: 2.04 s, Wall time: 2.72 sBR (Time results will vary.)
attachment:cycle_spr23.png
time posdict23.show()
CPU time: 0.57 s, Wall time: 0.71 sBR (Time results will vary.)
attachment:cycl_pd23.png
View many cycle graphs as a SAGE Graphics Array.
With the position dictionary filled:
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.CycleGraph(i+3) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:cycle_pd_array.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(16): ... spr = NX.cycle_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:cycle_spr_array.png
Diamond Graph
Info
- Returns a diamond graph with 4 nodes.
- A diamond graph is a square with one pair of diagonal nodes connected.
- This constructor depends on NetworkX numeric labeling.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the diamond graph is drawn as a diamond, with the first node on top, second on the left, third on the right, and fourth on the bottom; with the second and third node connected.
Code
pos_dict = [[0,1],[-1,0],[1,0],[0,-1]] import networkx G = networkx.diamond_graph() return graph.Graph(G, pos=pos_dict, name="Diamond Graph")
Examples
# Construct and show a diamond graph sage: g = graphs.DiamondGraph() sage: g.show()
attachment here
Empty Graphs
Info
- Returns an empty graph (0 nodes and 0 edges).
- This is useful for constructing graphs by adding edges and vertices individually or in a loop.
Plotting
- When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified.
Code
return graph.Graph()
Examples
Add one vertex to an empty graph.
sage: empty1 = graphs.EmptyGraph() sage: empty1.add_vertex() sage: empty1.show()
attachment:empty1.png
Use for loops to build a graph from an empty graph.
sage: empty2 = graphs.EmptyGraph() sage: for i in range(5): ... empty2.add_vertex() # add 5 nodes, labeled 0-4 ... sage: for i in range(3): ... empty2.add_edge(i,i+1) # add edges {[0:1],[1:2],[2:3]} ... sage: for i in range(4)[1:]: ... empty2.add_edge(4,i) # add edges {[1:4],[2:4],[3:4]} ... sage: empty2.show()
attachment:empty2.png
Grid2d Graphs
Info
- Returns a 2-dimensional grid graph with n1*n2 nodes (n1 rows and n2 columns).
- A 2d grid graph resembles a 2 dimensional grid. All inner nodes are connected to their 4 neighbors. Outer (non-corner) nodes are connected to their 3 neighbors. Corner nodes are connected to their 2 neighbors.
- This constructor depends on NetworkX numeric labels.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, nodes are labelled in (row, column) pairs with (0, 0) in the top left corner. Edges will always be horizontal and vertical - another advantage of filling the position dictionary.
Code
pos_dict = {} for i in range(n1): y = -i for j in range(n2): x = j pos_dict[i,j] = [x,y] import networkx G = networkx.grid_2d_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="2D Grid Graph")
Examples
# Construct and show a grid 2d graph # Rows = 5, Columns = 7 sage: g = graphs.Grid2dGraph(5,7) sage: g.show()
attachment here
House Graph
Info
- Returns a house graph with 5 nodes.
- A house graph is named for its shape. It is a triange (roof) over a square (walls).
- This constructor depends on NetworkX numeric labeling.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the house graph is drawn with the first node in the lower-left corner of the house, the second in the lower-right corner of the house. The third node is in the upper-left corner connecting the roof to the wall, and the fourth is in the upper-right corner connecting the roof to the walll. The fifth node is the top of the roof, connected only to the third and fourth.
Code
This has been updated! Change!
pos_dict = [[-1,0],[1,0],[-1,1],[1,1],[0,2]] import networkx G = networkx.house_graph() return graph.Graph(G, pos=pos_dict, name="House Graph") ==== Examples ==== {{{ # Construct and show a house graph sage: g = graphs.HouseGraph() sage: g.show()
attachment here
House X Graph
Info
- Returns a house X graph with 5 nodes.
- A house X graph is a house graph with two additional edges. The upper-right corner is connected to the lower-left. And the upper-left corner is connected to the lower-right.
- This constructor depends on NetworkX numeric labeling.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the house X graph is drawn with the first node in the lower-left corner of the house, the second in the lower-right corner of the house. The third node is in the upper-left corner connecting the roof to the wall, and the fourth is in the upper-right corner connecting the roof to the walll. The fifth node is the top of the roof, connected only to the third and fourth.
Code, has been updated!
pos_dict = [[-1,0],[1,0],[-1,1],[1,1],[0,2]] import networkx G = networkx.house_x_graph() return graph.Graph(G, pos=pos_dict, name="House Graph")
Examples
# Construct and show a house X graph sage: g = graphs.HouseXGraph() sage.: g.show()
attachment here
Krackhardt Kite Graph
Info
- Returns a Krackhardt kite graph with 10 nodes.
- This constructor depends on NetworkX numeric labeling.
- The Krackhardt kite graph was originally developed by David Krackhardt for the purpose of studying social networks. It is used to show the distinction between: degree centrality, betweeness centrality, and closeness centrality. For more information read the plotting section below in conjunction with the example.
References
Kreps, V. (2002). "Social Network Analysis". [http://www.fsu.edu/~spap/water/network/intro.htm Link]
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the graph is drawn left to right, in top to bottom row sequence of [2, 3, 2, 1, 1, 1] nodes on each row. This places the fourth node (3) in the center of the kite, with the highest degree.
- But the fourth node only connects nodes that are otherwise connected, or those in its clique (i.e.: Degree Centrality).
- The eigth (7) node is where the kite meets the tail. It has degree = 3, less than the average, but is the only connection between the kite and tail (i.e.: Betweenness Centrality).
- The sixth and seventh nodes (5 and 6) are drawn in the third row and have degree = 5. These nodes have the shortest path to all other nodes in the graph (i.e.: Closeness Centrality). Please execute the example for visualization.
Code
pos_dict = [[-1,4],[1,4],[-2,3],[0,3],[2,3],[-1,2],[1,2],[0,1],[0,0],[0,-1]] import networkx G = networkx.krackhardt_kite_graph() return graph.Graph(G, pos=pos_dict, name="Krackhardt Kite Graph")
Examples
# Construct and show a Krackhardt kite graph sage: g = graphs.KrackhardtKiteGraph() sage.: g.show()
attachment here
Ladder Graph
Edit conflict - your version:
# Construct and show a house X graph sage: g = graphs.HouseXGraph() sage.: g.show()
attachment here
Krackhardt Kite Graph
Info
- Returns a Krackhardt kite graph with 10 nodes.
- This constructor depends on NetworkX numeric labeling.
- The Krackhardt kite graph was originally developed by David Krackhardt for the purpose of studying social networks. It is used to show the distinction between: degree centrality, betweeness centrality, and closeness centrality. For more information read the plotting section below in conjunction with the example.
References
Kreps, V. (2002). "Social Network Analysis". [http://www.fsu.edu/~spap/water/network/intro.htm Link]
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, the graph is drawn left to right, in top to bottom row sequence of [2, 3, 2, 1, 1, 1] nodes on each row. This places the fourth node (3) in the center of the kite, with the highest degree.
- But the fourth node only connects nodes that are otherwise connected, or those in its clique (i.e.: Degree Centrality).
- The eigth (7) node is where the kite meets the tail. It has degree = 3, less than the average, but is the only connection between the kite and tail (i.e.: Betweenness Centrality).
- The sixth and seventh nodes (5 and 6) are drawn in the third row and have degree = 5. These nodes have the shortest path to all other nodes in the graph (i.e.: Closeness Centrality). Please execute the example for visualization.
Code
pos_dict = [[-1,4],[1,4],[-2,3],[0,3],[2,3],[-1,2],[1,2],[0,1],[0,0],[0,-1]] import networkx G = networkx.krackhardt_kite_graph() return graph.Graph(G, pos=pos_dict, name="Krackhardt Kite Graph")
Examples
# Construct and show a Krackhardt kite graph sage: g = graphs.KrackhardtKiteGraph() sage.: g.show()
attachment here
Ladder Graph
Lollipop Graph
Path Graph
Star Graphs
Info
- Returns a star graph with n+1 nodes.
- A Star graph is a basic structure where one node is connected to all other nodes.
- This constructor is dependant on NetworkX numeric labels.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each star graph will be displayed with the first (0) node in the center, the second node (1) at the top, with the rest following in a counterclockwise manner. (0) is the node connected to all other nodes.
- The star graph is a good opportunity to compare efficiency of filling a position dictionary vs. using the spring-layout algorithm for plotting. As far as display, the spring-layout should push all other nodes away from the (0) node, and thus look very similar to this constructor's positioning.
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
import networkx as NX pos_dict = {} pos_dict[0] = [0,0] for i in range(n+1)[1:]: x = float(functions.cos((pi/2) + ((2*pi)/n)*(i-1))) y = float(functions.sin((pi/2) + ((2*pi)/n)*(i-1))) pos_dict[i] = [x,y] G = NX.star_graph(n) return graph.Graph(G, pos=pos_dict, name="Star graph on %d vertices"%(n+1))
Examples
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.star_graph(3989); spring3989 = Graph(n)
CPU time: 0.08 s, Wall time: 0.10 sBR (Time Results will vary.)
time posdict3989 = graphs.StarGraph(3989)
CPU time: 5.43 s, Wall time: 7.41 sBR (Time results will vary.)
Compare the plotting speeds.
sage: n = NX.star_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.StarGraph(23)
time spring23.show()
CPU time: 2.31 s, Wall time: 3.14 sBR (Time results will vary.)
attachment:star_spr23.png
time posdict23.show()
CPU time: 0.68 s, Wall time: 0.80 sBR (Time results will vary.)
attachment:star_pd23.png
View many star graphs as a SAGE Graphics Array.
With the position dictionary filled:
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.StarGraph(i+3) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:star_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(16): ... spr = NX.star_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:star_array_spr.png
Wheel Graphs
Info
- Returns a Wheel graph with n nodes.
- A Wheel graph is a basic structure where one node is connected to all other nodes and those (outer) nodes are connected cyclically.
- This constructor depends on NetworkX numeric labels.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each wheel graph will be displayed with the first (0) node in the center, the second node at the top, and the rest following in a counterclockwise manner.
- With the wheel graph, we see that it doesn't take a very large n at all for the spring-layout to give a counter-intuitive display. (See Graphics Array examples below).
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
import networkx as NX pos_dict = {} pos_dict[0] = [0,0] for i in range(n)[1:]: x = float(functions.cos((pi/2) + ((2*pi)/(n-1))*(i-1))) y = float(functions.sin((pi/2) + ((2*pi)/(n-1))*(i-1))) pos_dict[i] = [x,y] G = NX.wheel_graph(n) return graph.Graph(G, pos=pos_dict, name="Wheel graph on %d vertices"%n)
Examples
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.wheel_graph(3989); spring3989 = Graph(n)
CPU time: 0.07 s, Wall time: 0.09 sbr (Time results will vary.)
time posdict3989 = graphs.WheelGraph(3989)
CPU time: 5.99 s, Wall time: 8.74 sbr (Time results will vary.)
Compare the plotting speeds.
sage: n = NX.wheel_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.WheelGraph(23)
time spring23.show()
CPU time: 2.24 s, Wall time: 3.00 sbr (Time results will vary.)
attachment:wheel_spr23.png
time posdict23.show()
CPU time: 0.68 s, Wall time: 1.14 sbr (Time results will vary.)
attachment:wheel_pd23.png
View many wheel graphs as a SAGE Graphics Array.
With the position dictionary filled:
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.WheelGraph(i+3) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:wheel_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(16): ... spr = NX.wheel_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:wheel_array_spr.png
Named Graphs
Petersen
Info
- The Petersen Graph is a named graph that consists of 10 vertices and 14 edges, usually drawn as a five-point star embedded in a pentagon.
- The Petersen Graph is a common counterexample. For example, it is not Hamiltonian.
Plotting
- When plotting the Petersen graph with the spring-layout algorithm, we see that this graph is not very symmetric and thus the display may not be very meaningful. Efficiency of construction and plotting is not an issue, as the Petersen graph
only has 10 vertices and 14 edges.
- Our labeling convention here is to start on the outer pentagon from the top, moving counterclockwise. Then the nodes on the inner star, starting at the top and moving counterclockwise.
Code
pos_dict = {} for i in range(5): x = float(functions.cos(pi/2 + ((2*pi)/5)*i)) y = float(functions.sin(pi/2 + ((2*pi)/5)*i)) pos_dict[i] = [x,y] for i in range(10)[5:]: x = float(0.5*functions.cos(pi/2 + ((2*pi)/5)*i)) y = float(0.5*functions.sin(pi/2 + ((2*pi)/5)*i)) pos_dict[i] = [x,y] P = graph.Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9],\ 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]},\ pos=pos_dict, name="Petersen graph") return P
Examples
Petersen Graph as constructed in this class:
sage: petersen_database = graphs.PetersenGraph() sage: petersen_database.show()
attachment:petersen_pos.png Petersen Graph plotted using the spring layout algorithm:
sage: petersen_spring = Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9],\ 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]}) sage: petersen_spring.show()
attachment:petersen_spring.png
Graph Families
Complete Graphs
Info
- Returns a complete graph on n nodes.
- A Complete Graph is a graph in which all nodes are connected to all other nodes.
- This constructor is dependant on vertices numbered 0 through n-1 in NetworkX complete_graph()
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete graph will be displayed with the first (0) node at the top, with the rest following in a counterclockwise manner.
- In the complete graph, there is a big difference visually in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph, making it clear which nodes an edge is connected to. But the complete graph offers a good example of how the spring-layout works. The edges push outward (everything is connected), causing the graph to appear as a 3-dimensional pointy ball. (See examples below).
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
import networkx as NX pos_dict = {} for i in range(n): x = float(functions.cos((pi/2) + ((2*pi)/n)*i)) y = float(functions.sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] G = NX.complete_graph(n) return graph.Graph(G, pos=pos_dict, name="Complete graph on %d vertices"%n)
Examples
Petersen Graph as constructed in this class:
sage: petersen_database = graphs.PetersenGraph() sage: petersen_database.show()
attachment:petersen_pos.png Petersen Graph plotted using the spring layout algorithm:
sage: petersen_spring = Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9],\ 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]}) sage: petersen_spring.show()
attachment:petersen_spring.png
Graph Families
Complete Graphs
Info
- Returns a complete graph on n nodes.
- A Complete Graph is a graph in which all nodes are connected to all other nodes.
- This constructor is dependant on vertices numbered 0 through n-1 in NetworkX complete_graph()
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete graph will be displayed with the first (0) node at the top, with the rest following in a counterclockwise manner.
- In the complete graph, there is a big difference visually in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph, making it clear which nodes an edge is connected to. But the complete graph offers a good example of how the spring-layout works. The edges push outward (everything is connected), causing the graph to appear as a 3-dimensional pointy ball. (See examples below).
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
import networkx as NX pos_dict = {} for i in range(n): x = float(functions.cos((pi/2) + ((2*pi)/n)*i)) y = float(functions.sin((pi/2) + ((2*pi)/n)*i)) pos_dict[i] = [x,y] G = NX.complete_graph(n) return graph.Graph(G, pos=pos_dict, name="Complete graph on %d vertices"%n) ---- /!\ '''End of edit conflict''' ----
Examples
Edit conflict - other version:
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.complete_graph(1559); spring1559 = Graph(n)
CPU time: 6.85 s, Wall time: 9.71 sBR(Time results vary.)
time posdict1559 = graphs.CompleteGraph(1559)
CPU time: 9.67 s, Wall time: 11.75 sBR(Time results vary.)
Compare the plotting speeds.
sage: n = NX.complete_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.CompleteGraph(23)
time spring23.show()
CPU time: 3.51 s, Wall time: 4.29 sBR(Time Results will vary.)
attachment:complete_spr23.png
time posdict23.show()
CPU time: 0.82 s, Wall time: 0.96 sBR(Time Results will vary.)
attachment:complete_pd23.png
View many Complete graphs as a SAGE Graphics Array. With the position dictionary filled:
Edit conflict - your version:
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.complete_graph(1559); spring1559 = Graph(n)
CPU time: 6.85 s, Wall time: 9.71 sBR(Time results vary.)
time posdict1559 = graphs.CompleteGraph(1559)
CPU time: 9.67 s, Wall time: 11.75 sBR(Time results vary.)
Compare the plotting speeds.
sage: n = NX.complete_graph(23) sage: spring23 = Graph(n) sage: posdict23 = graphs.CompleteGraph(23)
time spring23.show()
CPU time: 3.51 s, Wall time: 4.29 sBR(Time Results will vary.)
attachment:complete_spr23.png
time posdict23.show()
CPU time: 0.82 s, Wall time: 0.96 sBR(Time Results will vary.)
attachment:complete_pd23.png
View many Complete graphs as a SAGE Graphics Array. With the position dictionary filled:
End of edit conflict
sage: g = [] sage: j = [] ---- /!\ '''Edit conflict - other version:''' ---- sage: for i in range(9): ... k = graphs.CompleteGraph(i+3) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ---- /!\ '''Edit conflict - your version:''' ---- sage: for i in range(9): ... k = graphs.CompleteGraph(i+3) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ---- /!\ '''End of edit conflict''' ---- ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
Edit conflict - other version:
attachment:complete_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:complete_array_spr.png
Complete Bipartite Graphs
Info
- Returns a Complete Bipartite Graph sized n1+n2, with each of the nodes [0,(n1-1)] connected to each of the nodes [n1,(n2-1)] and vice versa.
- A Complete Bipartite Graph is a graph with its vertices partitioned into two groups, V1 and V2. Each v in V1 is connected to every v in V2, and vice versa.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete bipartite graph will be displayed with the first n1 nodes on the top row (at y=1) from left to right. The remaining n2 nodes appear at y=0, also from left to right. The shorter row (partition with fewer nodes) is stretched to the same length as the longer row, unless the shorter row has 1 node; in which case it is centered. The x values in the plot are in domain [0,max{n1,n2}].
- In the Complete Bipartite graph, there is a visual difference in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph and separates the partitioned nodes, making it clear which nodes an edge is connected to. The Complete Bipartite graph plotted with the spring-layout algorithm tends to center the nodes in n1 (see spring_med in examples below), thus overlapping its nodes and edges, making it typically hard to decipher.
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
pos_dict = {} c1 = 1 # scaling factor for top row c2 = 1 # scaling factor for bottom row c3 = 0 # pad to center if top row has 1 node c4 = 0 # pad to center if bottom row has 1 node if n1 > n2: if n2 == 1: c4 = (n1-1)/2 else: c2 = ((n1-1)/(n2-1)) elif n2 > n1: if n1 == 1: c3 = (n2-1)/2 else: c1 = ((n2-1)/(n1-1)) for i in range(n1): x = c1*i + c3 y = 1 pos_dict[i] = [x,y] for i in range(n1+n2)[n1:]: x = c2*(i-n1) + c4 y = 0 pos_dict[i] = [x,y] G = NX.complete_bipartite_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="Complete bipartite graph on %d vertices"%(n1+n2))
Examples
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.complete_bipartite_graph(389,157); spring_big = Graph(n)
CPU time: 9.28 s, Wall time: 11.02 sBR(Time results will vary.)
time posdict_big = graphs.CompleteBipartiteGraph(389,157)
CPU time: 10.72 s, Wall time: 13.84 sBR(Time results will vary.)
Compare the plotting speeds.
sage: n = NX.complete_bipartite_graph(11,17) sage: spring_med = Graph(n) sage: posdict_med = graphs.CompleteBipartiteGraph(11,17)
time spring_med.show()
CPU time: 3.84 s, Wall time: 4.49 sBR(Time results will vary.)
attachment:compbip_spr_med.png
time posdict_med.show()
CPU time: 0.96 s, Wall time: 1.14 sBR(Time results will vary.)
attachment:compbip_pd_med.png
View many Complete Bipartite graphs as a SAGE Graphics Array. With the position dictionary filled:
sage: g = [] sage: j = [] sage: for i in range(9): ... k = graphs.CompleteBipartiteGraph(i+1,4) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:compbip_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_bipartite_graph(i+1,4) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:compbip_array.spr.png
Random Graph Generators
RandomGNP
Info
- Returns a Random graph on n nodes. Each edge is inserted independently with probability p.
- If p is small, use RandomGNPFast. See NetworkX documentation.
- C.f. P. Erdos and A. Renyi, On Random Graphs, Publ. Math. 6, 290 (1959). E. N. Gilbert, Random Graphs, Ann. Math. Stat., 30, 1141 (1959).
Plotting
- When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified.
Code
import networkx as NX G = NX.gnp_random_graph(n, p, seed) return graph.Graph(G)
Examples
Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs
time regular_sparse = graphs.RandomGNP(1559,.22)
CPU time: 31.79 s, Wall time: 38.78 sBR(Time results will vary.)
time fast_sparse = graphs.RandomGNPFast(1559,.22)
CPU time: 21.72 s, Wall time: 26.44 sBR(Time results will vary.)
Dense Graphs
time regular_dense = graphs.RandomGNP(1559,.88)
CPU time: 38.75 s, Wall time: 47.65 sBR(Time results will vary.)
time fast_dense = graphs.RandomGNP(1559,.88)
CPU time: 39.15 s, Wall time: 48.22 sBR(Time results will vary.)
Plot a random graph on 12 nodes with p = .71
sage: gnp = graphs.RandomGNP(12,.71) sage: gnp.show()
attachment:rand_reg.png
View many random graphs using a SAGE Graphics Array
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNP(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:rand_array_reg.png
RandomGNPFast
Info
- Returns a Random graph on n nodes. Each edge is inserted independently with probability p.
- Use for small p (sparse graphs). See NetworkX documentation.
Plotting
- When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified.
Code
import networkx as NX G = NX.fast_gnp_random_graph(n, p, seed) return graph.Graph(G)
Examples
Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs
time regular_sparse = graphs.RandomGNP(1559,.22)
CPU time: 31.79 s, Wall time: 38.78 sBR(Time results will vary.)
time fast_sparse = graphs.RandomGNPFast(1559,.22)
CPU time: 21.72 s, Wall time: 26.44 sBR(Time results will vary.)
Dense Graphs
time regular_dense = graphs.RandomGNP(1559,.88)
CPU time: 38.75 s, Wall time: 47.65 sBR(Time results will vary.)
time fast_dense = graphs.RandomGNP(1559,.88)
CPU time: 39.15 s, Wall time: 48.22 sBR(Time results will vary.)
Plot a random graph on 12 nodes with p = .71
sage: fast = graphs.RandomGNPFast(12,.71) sage: fast.show()
attachment:rand_fast.png
View many random graphs using a SAGE Graphics Array
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNPFast(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:rand_array_fast.png
Edit conflict - your version:
attachment:complete_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_graph(i+3) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:complete_array_spr.png
Complete Bipartite Graphs
Info
- Returns a Complete Bipartite Graph sized n1+n2, with each of the nodes [0,(n1-1)] connected to each of the nodes [n1,(n2-1)] and vice versa.
- A Complete Bipartite Graph is a graph with its vertices partitioned into two groups, V1 and V2. Each v in V1 is connected to every v in V2, and vice versa.
Plotting
- Upon construction, the position dictionary is filled to override the spring-layout algorithm. By convention, each complete bipartite graph will be displayed with the first n1 nodes on the top row (at y=1) from left to right. The remaining n2 nodes appear at y=0, also from left to right. The shorter row (partition with fewer nodes) is stretched to the same length as the longer row, unless the shorter row has 1 node; in which case it is centered. The x values in the plot are in domain [0,max{n1,n2}].
- In the Complete Bipartite graph, there is a visual difference in using the spring-layout algorithm vs. the position dictionary used in this constructor. The position dictionary flattens the graph and separates the partitioned nodes, making it clear which nodes an edge is connected to. The Complete Bipartite graph plotted with the spring-layout algorithm tends to center the nodes in n1 (see spring_med in examples below), thus overlapping its nodes and edges, making it typically hard to decipher.
- Filling the position dictionary in advance adds O(n) to the constructor. Feel free to race the constructors below in the examples section. The much larger difference is the time added by the spring-layout algorithm when plotting. (Also shown in the example below). The spring model is typically described as O(n^3), as appears to be the case in the NetworkX source code.
Code
pos_dict = {} c1 = 1 # scaling factor for top row c2 = 1 # scaling factor for bottom row c3 = 0 # pad to center if top row has 1 node c4 = 0 # pad to center if bottom row has 1 node if n1 > n2: if n2 == 1: c4 = (n1-1)/2 else: c2 = ((n1-1)/(n2-1)) elif n2 > n1: if n1 == 1: c3 = (n2-1)/2 else: c1 = ((n2-1)/(n1-1)) for i in range(n1): x = c1*i + c3 y = 1 pos_dict[i] = [x,y] for i in range(n1+n2)[n1:]: x = c2*(i-n1) + c4 y = 0 pos_dict[i] = [x,y] G = NX.complete_bipartite_graph(n1,n2) return graph.Graph(G, pos=pos_dict, name="Complete bipartite graph on %d vertices"%(n1+n2))
Examples
The following examples require NetworkX (to use default):
sage: import networkx as NX
Compare the constructor speeds.
time n = NX.complete_bipartite_graph(389,157); spring_big = Graph(n)
CPU time: 9.28 s, Wall time: 11.02 sBR(Time results will vary.)
time posdict_big = graphs.CompleteBipartiteGraph(389,157)
CPU time: 10.72 s, Wall time: 13.84 sBR(Time results will vary.)
Compare the plotting speeds.
sage: n = NX.complete_bipartite_graph(11,17) sage: spring_med = Graph(n) sage: posdict_med = graphs.CompleteBipartiteGraph(11,17)
time spring_med.show()
CPU time: 3.84 s, Wall time: 4.49 sBR(Time results will vary.)
attachment:compbip_spr_med.png
time posdict_med.show()
CPU time: 0.96 s, Wall time: 1.14 sBR(Time results will vary.)
attachment:compbip_pd_med.png
View many Complete Bipartite graphs as a SAGE Graphics Array. With the position dictionary filled:
sage: g = [] sage: j = [] sage: for i in range(9): ... k = graphs.CompleteBipartiteGraph(i+1,4) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:compbip_array_pd.png
With the spring-layout algorithm:
sage: g = [] sage: j = [] sage: for i in range(9): ... spr = NX.complete_bipartite_graph(i+1,4) ... k = Graph(spr) ... g.append(k) ... sage: for i in range(3): ... n = [] ... for m in range(3): ... n.append(g[3*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:compbip_array.spr.png
Random Graph Generators
RandomGNP
Info
- Returns a Random graph on n nodes. Each edge is inserted independently with probability p.
- If p is small, use RandomGNPFast. See NetworkX documentation.
- C.f. P. Erdos and A. Renyi, On Random Graphs, Publ. Math. 6, 290 (1959). E. N. Gilbert, Random Graphs, Ann. Math. Stat., 30, 1141 (1959).
Plotting
- When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified.
Code
import networkx as NX G = NX.gnp_random_graph(n, p, seed) return graph.Graph(G)
Examples
Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs
time regular_sparse = graphs.RandomGNP(1559,.22)
CPU time: 31.79 s, Wall time: 38.78 sBR(Time results will vary.)
time fast_sparse = graphs.RandomGNPFast(1559,.22)
CPU time: 21.72 s, Wall time: 26.44 sBR(Time results will vary.)
Dense Graphs
time regular_dense = graphs.RandomGNP(1559,.88)
CPU time: 38.75 s, Wall time: 47.65 sBR(Time results will vary.)
time fast_dense = graphs.RandomGNP(1559,.88)
CPU time: 39.15 s, Wall time: 48.22 sBR(Time results will vary.)
Plot a random graph on 12 nodes with p = .71
sage: gnp = graphs.RandomGNP(12,.71) sage: gnp.show()
attachment:rand_reg.png
View many random graphs using a SAGE Graphics Array
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNP(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:rand_array_reg.png
RandomGNPFast
Info
- Returns a Random graph on n nodes. Each edge is inserted independently with probability p.
- Use for small p (sparse graphs). See NetworkX documentation.
Plotting
- When plotting, this graph will use the default spring-layout algorithm, unless a position dictionary is specified.
Code
import networkx as NX G = NX.fast_gnp_random_graph(n, p, seed) return graph.Graph(G)
Examples
Compare the speed of RandomGNP and RandomGNPFast: Sparse Graphs
time regular_sparse = graphs.RandomGNP(1559,.22)
CPU time: 31.79 s, Wall time: 38.78 sBR(Time results will vary.)
time fast_sparse = graphs.RandomGNPFast(1559,.22)
CPU time: 21.72 s, Wall time: 26.44 sBR(Time results will vary.)
Dense Graphs
time regular_dense = graphs.RandomGNP(1559,.88)
CPU time: 38.75 s, Wall time: 47.65 sBR(Time results will vary.)
time fast_dense = graphs.RandomGNP(1559,.88)
CPU time: 39.15 s, Wall time: 48.22 sBR(Time results will vary.)
Plot a random graph on 12 nodes with p = .71
sage: fast = graphs.RandomGNPFast(12,.71) sage: fast.show()
attachment:rand_fast.png
View many random graphs using a SAGE Graphics Array
sage: g = [] sage: j = [] sage: for i in range(16): ... k = graphs.RandomGNPFast(i+3,.43) ... g.append(k) ... sage: for i in range(4): ... n = [] ... for m in range(4): ... n.append(g[4*i + m].plot(node_size=50, vertex_labels=False)) ... j.append(n) ... sage: G = sage.plot.plot.GraphicsArray(j) sage: G.show()
attachment:rand_array_fast.png
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