aaa16797 Posted July 13, 2014 Posted July 13, 2014 I dont even know if there is an equation for this, but what is the equation for a quarter circle that has a center at the origin?
Acme Posted July 13, 2014 Posted July 13, 2014 I dont even know if there is an equation for this, but what is the equation for a quarter circle that has a center at the origin? Do you want the area or the length of the arc?
aaa16797 Posted July 13, 2014 Author Posted July 13, 2014 im just wondering what the equation of it would be if it were plotted on a graph
Acme Posted July 13, 2014 Posted July 13, 2014 Area = π × r2 : 1/4 of that would be 1/4 × π × r2 or Area of sector = 1/2 × r2 × θ : θ = angle in radians :1/4 circle is 90º = 0.5π rad = 1.5707963268 rad Area of 1/4 circle = 1/2 × r2 × 1.5707963268 Circumference = 2 × π × r : 1/4 of that would be 1/4 × 2 × π × r = 1/2 × π × r
aaa16797 Posted July 13, 2014 Author Posted July 13, 2014 Area = π × r2 : 1/4 of that would be 1/4 × π × r2 or Area of sector = 1/2 × r2 × θ : θ = angle in radians :1/4 circle is 90º = 0.5π rad = 1.5707963268 rad Area of 1/4 circle = 1/2 × r2 × 1.5707963268 Circumference = 2 × π × r : 1/4 of that would be 1/4 × 2 × π × r = 1/2 × π × r oh sorry i don't think u understand what i mean im talking about the equation of a quarter circle on a graph which has an origin as its center
Acme Posted July 13, 2014 Posted July 13, 2014 oh sorry i don't think u understand what i mean im talking about the equation of a quarter circle on a graph which has an origin as its center ?? x^2+y^2<=r^2 and 0<=tan^(-1)(x, y)<=pi/2 (assuming radius r, center (0, 0), and rotation angle 0°)
imatfaal Posted July 13, 2014 Posted July 13, 2014 Well a circle is (x-a)^2+(y-b)^2=r^2 where a and b are coordinates of the centre and r is the radius - you cannot get a simple function mapping as multiple x's give the same y - for only positive x and y would give you a quarter circle (edge only) in the top right quadrant. 1
Daedalus Posted July 14, 2014 Posted July 14, 2014 (edited) I dont even know if there is an equation for this, but what is the equation for a quarter circle that has a center at the origin? Although you worded incorrectly, I believe I know what you're asking. However, there isn't an equation that is defined only for a quarter circle without restricting it to some interval such as [latex]F\left(\theta\right)=\left \langle r\,\text{cos}\,\theta,\ r\,\text{sin}\,\theta \right \rangle \ \ \left \{r,\theta\in\mathbb{R}\,\vert \, 0 \le \theta \le 45^\circ \right \}[/latex] Here we have the parametric equation for a circle which makes defining the [latex]x[/latex] and [latex]y[/latex] coordinates easier as you are wanting to restrict the equation according to a specific angle. The interval [[latex]0,45^\circ[/latex]] is an arbitrary choice that is dependent upon our parametrization of the circle or vice versa. We can achieve the same restriction using an interval [[latex]0,1[/latex]]. [latex]F\left(t\right)=\left \langle r\,\text{cos}\left(45 t\right),\ r\,\text{sin}\left(45 t\right) \right \rangle \ \ \left \{r,t\in\mathbb{R}\,\vert \, 0 \le t \le 1 \right \}[/latex] Given the equation for a circle that Imatfaal has provided [math]x^2+y^2=r^2[/math], we can demonstrate that our parametric equation does indeed satisfy the conditions of the equation for a circle centered at the origin - (0,0). [math]x=r\,\text{cos}\,\theta[/math] [math]y=r\,\text{sin}\,\theta[/math] [math]\left(r\,\text{cos}\,\theta\right)^2+\left(r\,\text{sin}\,\theta\right)^2=r^2[/math] [math]r^2\,\text{cos}^2\theta+r^2\,\text{sin}^2\theta=r^2[/math] [math]r^2\left(\text{cos}^2\theta+\text{sin}^2\theta\right)=r^2[/math] Use the Pythagorean trigonometric identity to simplify the equation. [math]\text{cos}^2\theta+\text{sin}^2\theta=1[/math] [math]r^2\left(1\right)=r^2[/math] [math]r=r[/math] Edited July 14, 2014 by Daedalus
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