poj2007 Scrambled Polygon (叉积极角排序)
来源:互联网 发布:linux crontab 权限 编辑:程序博客网 时间:2024/06/05 23:45
题目链接:
http://poj.org/problem?id=2007
Scrambled Polygon
Time Limit: 1000MS Memory Limit: 30000KTotal Submissions: 7648 Accepted: 3641
Description
A closed polygon is a figure bounded by a finite number of line segments. The intersections of the bounding line segments are called the vertices of the polygon. When one starts at any vertex of a closed polygon and traverses each bounding line segment exactly once, one comes back to the starting vertex.
A closed polygon is called convex if the line segment joining any two points of the polygon lies in the polygon. Figure 1 shows a closed polygon which is convex and one which is not convex. (Informally, a closed polygon is convex if its border doesn't have any "dents".)
The subject of this problem is a closed convex polygon in the coordinate plane, one of whose vertices is the origin (x = 0, y = 0). Figure 2 shows an example. Such a polygon will have two properties significant for this problem.
The first property is that the vertices of the polygon will be confined to three or fewer of the four quadrants of the coordinate plane. In the example shown in Figure 2, none of the vertices are in the second quadrant (where x < 0, y > 0).
To describe the second property, suppose you "take a trip" around the polygon: start at (0, 0), visit all other vertices exactly once, and arrive at (0, 0). As you visit each vertex (other than (0, 0)), draw the diagonal that connects the current vertex with (0, 0), and calculate the slope of this diagonal. Then, within each quadrant, the slopes of these diagonals will form a decreasing or increasing sequence of numbers, i.e., they will be sorted. Figure 3 illustrates this point.
A closed polygon is called convex if the line segment joining any two points of the polygon lies in the polygon. Figure 1 shows a closed polygon which is convex and one which is not convex. (Informally, a closed polygon is convex if its border doesn't have any "dents".)
The subject of this problem is a closed convex polygon in the coordinate plane, one of whose vertices is the origin (x = 0, y = 0). Figure 2 shows an example. Such a polygon will have two properties significant for this problem.
The first property is that the vertices of the polygon will be confined to three or fewer of the four quadrants of the coordinate plane. In the example shown in Figure 2, none of the vertices are in the second quadrant (where x < 0, y > 0).
To describe the second property, suppose you "take a trip" around the polygon: start at (0, 0), visit all other vertices exactly once, and arrive at (0, 0). As you visit each vertex (other than (0, 0)), draw the diagonal that connects the current vertex with (0, 0), and calculate the slope of this diagonal. Then, within each quadrant, the slopes of these diagonals will form a decreasing or increasing sequence of numbers, i.e., they will be sorted. Figure 3 illustrates this point.
Input
The input lists the vertices of a closed convex polygon in the plane. The number of lines in the input will be at least three but no more than 50. Each line contains the x and y coordinates of one vertex. Each x and y coordinate is an integer in the range -999..999. The vertex on the first line of the input file will be the origin, i.e., x = 0 and y = 0. Otherwise, the vertices may be in a scrambled order. Except for the origin, no vertex will be on the x-axis or the y-axis. No three vertices are colinear.
Output
The output lists the vertices of the given polygon, one vertex per line. Each vertex from the input appears exactly once in the output. The origin (0,0) is the vertex on the first line of the output. The order of vertices in the output will determine a trip taken along the polygon's border, in the counterclockwise direction. The output format for each vertex is (x,y) as shown below.
Sample Input
0 070 -5060 30-30 -5080 2050 -6090 -20-30 -40-10 -6090 10
Sample Output
(0,0)(-30,-40)(-30,-50)(-10,-60)(50,-60)(70,-50)(90,-20)(90,10)(80,20)(60,30)题目大意:
给你几个点让你以原点为起点,逆时针输出这几个点。直接进行叉积极角排序即可,可是我以前没学过叉积,就找资料恶补了一下。
<strong><span style="font-size:18px;"> 向量的叉积可以用来判断点在直线的某侧。进而可以解决点是否在三角形内,两个矩形是否重叠等问题。向量的叉积的模表示这两个向量围成的平行四边形的面积。 设矢量P = ( x1, y1 ),Q = ( x2, y2 ),则矢量叉积定义为由(0,0)、p1、p2和p1+p2所组成的平行四边形的带符号的面积,即:P×Q = x1*y2 - x2*y1,其结果是一个伪矢量。 显然有性质 P × Q = - ( Q × P ) 和 P × ( - Q ) = - ( P × Q )。 叉积的一个非常重要性质是可以通过它的符号判断两矢量相互之间的顺逆时针关系: 若 P × Q > 0 , 则P在Q的顺时针方向。 若 P × Q < 0 , 则P在Q的逆时针方向。 若 P × Q = 0 , 则P与Q共线,但可能同向也可能反向。 叉积的方向与进行叉积的两个向量都垂直,所以叉积向量即为这两个向量构成平面的法向量。 如果向量叉积为零向量,那么这两个向量是平行关系。 因为向量叉积是这两个向量平面的法向量,如果两个向量平行无法形成一个平面,其对应也没有平面法向量。所以,两个向量平行时,其向量叉积为零。</span></strong>AC代码:
#include<iostream>#include<stdio.h>#include<cmath>#include<complex>#include<algorithm>#define max(a,b) (a)>(b)?(a):(b)#define min(a,b) (a)<(b)?(a):(b)#define EPS 1e-8using namespace std;struct point { double x,y;};point convex[50];double cross(const point &p1, const point &p2, const point &q1, const point &q2){ return (q2.y - q1.y)*(p2.x - p1.x) - (q2.x - q1.x)*(p2.y - p1.y);//求叉积}bool cmp(const point &a, const point &b){ point origin; origin.x = origin.y = 0; return cross(origin,b,origin,a) < 0;//这里是叉积小于0的返回}int main(){ int cnt = 0; while (scanf("%lf%lf",&convex[cnt].x,&convex[cnt].y) != EOF) { ++cnt; } sort(convex+1,convex+cnt,cmp); for (int i(0); i<cnt; ++i) { cout<<"("<<convex[i].x<<","<<convex[i].y<<")"<<endl; } return 0;}
0 0
- poj2007 Scrambled Polygon (叉积极角排序)
- poj2007-Scrambled Polygon (极角排序)
- poj2007 Scrambled Polygon【极角排序】
- Scrambled Polygon(poj2007极角排序输出凸包)
- [POJ2007]Scrambled Polygon(计算几何)
- POJ2007 Scrambled Polygon
- POJ2007 Scrambled Polygon
- POJ2007-Scrambled Polygon
- POJ2007--Scrambled Polygon
- POJ2007 Scrambled Polygon
- POJ2007 Scrambled Polygon
- poj2007——Scrambled Polygon
- Scrambled Polygon (极角排序)
- POJ2007 Scrambled Polygon 凸多边形顶点输出
- POJ 2007 Scrambled Polygon (极角排序+叉乘)
- poj 2007 Scrambled Polygon(极角排序)
- POJ 2007 Scrambled Polygon(简单极角排序)
- POJ 2007:Scrambled Polygon (极角排序)
- Android中Intent的几种使用方法
- ABPersonViewController不显示除了名称的属性
- UVa 10596 - Morning Walk
- hdoj The mook jong 5366 (简单规律 打表)
- 数论之 素因子分解,素数筛选法,欧拉函数和扩展欧几里得算法 (整理)
- poj2007 Scrambled Polygon (叉积极角排序)
- BZOJ 1356 [Baltic2009]Rectangle 数学
- 类型参数约束
- 优秀程序员的45个习惯
- Java enum的集合用法
- Xcode中的调试工具栏简介
- 数据结构基础1_顺序表
- tcp拥塞控制时间轴上三种状态的关系,慢启动,拥塞避免,以及快速恢复的教学状态图。
- 教你如何迅速秒杀掉:99%的海量数据处理面试题