{"id":777,"date":"2017-11-14T13:48:09","date_gmt":"2017-11-14T13:48:09","guid":{"rendered":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/chapter\/keplers-laws-of-planetary-motion\/"},"modified":"2017-11-18T01:30:26","modified_gmt":"2017-11-18T01:30:26","slug":"keplers-laws-of-planetary-motion","status":"publish","type":"chapter","link":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/chapter\/keplers-laws-of-planetary-motion\/","title":{"raw":"Kepler&#8217;s Laws of Planetary Motion","rendered":"Kepler&#8217;s Laws of Planetary Motion"},"content":{"raw":"\n<div class=\"textbox learning-objectives\">\n<h3>Learning Objectives<\/h3>\n<p>By the end of this section, you will be able to:<\/p>\n<ul>\n<li>Describe the conic sections and how they relate to orbital motion<\/li>\n<li>Describe how orbital velocity is related to conservation of angular momentum<\/li>\n<li>Determine the period of an elliptical orbit from its major axis<\/li>\n<\/ul>\n<\/div>\n<p id=\"fs-id1168329287987\">Using the precise data collected by Tycho Brahe, Johannes Kepler carefully analyzed the positions in the sky of all the known planets and the Moon, plotting their positions at regular intervals of time. From this analysis, he formulated three laws, which we address in this section.<\/p>\n<div class=\"bc-section section\" id=\"fs-id1168329183887\">\n<h3>Kepler\u2019s First Law<\/h3>\n<p>The prevailing view during the time of Kepler was that all planetary orbits were circular. The data for Mars presented the greatest challenge to this view and that eventually encouraged Kepler to give up the popular idea. <span>Kepler\u2019s first law<\/span> states that every planet moves along an ellipse, with the Sun located at a focus of the ellipse. An ellipse is defined as the set of all points such that the sum of the distance from each point to two foci is a constant. <a href=\"#CNX_UPhysics_13_05_Ellipse\" class=\"autogenerated-content\">(Figure)<\/a> shows an ellipse and describes a simple way to create it.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_Ellipse\">\n<div class=\"bc-figcaption figcaption\">(a) An ellipse is a curve in which the sum of the distances from a point on the curve to two foci [latex]\\left({f}_{1}\\phantom{\\rule{0.2em}{0ex}}\\text{and}\\phantom{\\rule{0.2em}{0ex}}{f}_{2}\\right)[\/latex] is a constant. From this definition, you can see that an ellipse can be created in the following way. Place a pin at each focus, then place a loop of string around a pencil and the pins. Keeping the string taught, move the pencil around in a complete circuit. If the two foci occupy the same place, the result is a circle\u2014a special case of an ellipse. (b) For an elliptical orbit, if [latex]m\\ll M[\/latex], then <em>m<\/em> follows an elliptical path with <em>M<\/em> at one focus. More exactly, both <em>m<\/em> and <em>M<\/em> move in their own ellipse about the common center of mass.<\/div>\n<p><span id=\"fs-id1168327148139\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_Ellipse.jpg\" alt=\"Figure a shows an x y coordinate system and an ellipse centered on the origin with foci f 1 on the left and f 2 on the right, both on the x axis. Focus f 1 is also labeled M. A point above focus f 2 is labeled m. The right triangle formed by f 1, f 2, and m is shown in red. Figure b shows a similar ellipse, with the sun shown and labeled as M and as Sun at f 1. A planet mass m is shown above f 1, at a vertical distance r from f 1. The location where the ellipse intersects the horizontal axis on the left is labeled as point A, and the location where the ellipse intersects the horizontal axis on the right is labeled as point B.\"><\/span><\/p><\/div>\n<p id=\"fs-id1168329179515\">For elliptical orbits, the point of closest approach of a planet to the Sun is called the <span>perihelion<\/span>. It is labeled point <em>A<\/em> in <a href=\"#CNX_UPhysics_13_05_Ellipse\" class=\"autogenerated-content\">(Figure)<\/a>. The farthest point is the <span>aphelion<\/span> and is labeled point <em>B<\/em> in the figure. For the Moon\u2019s orbit about Earth, those points are called the perigee and apogee, respectively.<\/p>\n<p id=\"fs-id1168329288308\">An ellipse has several mathematical forms, but all are a specific case of the more general equation for conic sections. There are four different conic sections, all given by the equation<\/p>\n<div id=\"fs-id1168329125888\" class=\"equation-callout\">\n<div>[latex]\\frac{\\alpha }{r}=1+e\\text{cos}\\theta .[\/latex]<\/div>\n<\/div>\n<p id=\"fs-id1168327081841\">The variables <em>r<\/em> and [latex]\\theta [\/latex] are shown in <a href=\"#CNX_UPhysics_13_05_conic1\" class=\"autogenerated-content\">(Figure)<\/a> in the case of an ellipse. The constants [latex]\\alpha [\/latex] and <em>e<\/em> are determined by the total energy and angular momentum of the satellite at a given point. The constant <em>e<\/em> is called the eccentricity. The values of [latex]\\alpha [\/latex] and <em>e<\/em> determine which of the four conic sections represents the path of the satellite.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_conic1\">\n<div class=\"bc-figcaption figcaption\">As before, the distance between the planet and the Sun is <em>r<\/em>, and the angle measured from the <em>x<\/em>-axis, which is along the major axis of the ellipse, is [latex]\\theta [\/latex].<\/div>\n<p><span id=\"fs-id1168326938983\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_conic1.jpg\" alt=\"An x y coordinate system and an ellipse centered on the origin with foci f 1 on the left and f 2 on the right, both on the x axis, are shown. Focus f 1 is also labeled M. A point on the ellipse in the first quadrant is labeled m. The horizontal segment connecting the foci f 1 and f 2, and the segment connecting f 1 and m are shown in red. The angle between those segments is labeled Theta.\"><\/span><\/p><\/div>\n<p id=\"fs-id1168326747212\">One of the real triumphs of Newton\u2019s law of universal gravitation, with the force proportional to the inverse of the distance squared, is that when it is combined with his second law, the solution for the path of any satellite is a conic section. Every path taken by <em>m<\/em> is one of the four conic sections: a circle or an ellipse for bound or closed orbits, or a parabola or hyperbola for unbounded or open orbits. These conic sections are shown in <a href=\"#CNX_UPhysics_13_05_conic2\" class=\"autogenerated-content\">(Figure)<\/a>.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_conic2\">\n<div class=\"bc-figcaption figcaption\">All motion caused by an inverse square force is one of the four conic sections and is determined by the energy and direction of the moving body.<\/div>\n<p><span id=\"fs-id1168329254205\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_conic2.jpg\" alt=\"A cone and its conic sections is shown. At the top a horizontal cut is shaded and a dashed line shown across the shading. This section is labeled circle. Below this a diagonal cut and line are shown. The line and cut intersect the sides of the cone. This section is labeled ellipse. Next is a diagonal cut and line that intersect the sides and the bottom of the cone and are labeled parabola. The last section is a vertical line and shaded cut labeled hyperbola\"><\/span><\/p><\/div>\n<p>If the total energy is negative, then [latex]0\\le e&lt;1[\/latex], and <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> represents a bound or closed orbit of either an ellipse or a circle, where [latex]e=0[\/latex]. [You can see from <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> that for [latex]e=0[\/latex], [latex]r=\\alpha [\/latex], and hence the radius is constant.] For ellipses, the eccentricity is related to how oblong the ellipse appears. A circle has zero eccentricity, whereas a very long, drawn-out ellipse has an eccentricity near one.<\/p>\n<p id=\"fs-id1168329193027\">If the total energy is exactly zero, then [latex]e=1[\/latex] and the path is a parabola. Recall that a satellite with zero total energy has exactly the escape velocity. (The parabola is formed only by slicing the cone parallel to the tangent line along the surface.) Finally, if the total energy is positive, then [latex]e&gt;1[\/latex] and the path is a hyperbola. These last two paths represent unbounded orbits, where <em>m<\/em> passes by <em>M<\/em> once and only once. This situation has been observed for several comets that approach the Sun and then travel away, never to return.<\/p>\n<p>We have confined ourselves to the case in which the smaller mass (planet) orbits a much larger, and hence stationary, mass (Sun), but <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> also applies to any two gravitationally interacting masses. Each mass traces out the exact same-shaped conic section as the other. That shape is determined by the total energy and angular momentum of the system, with the center of mass of the system located at the focus. The ratio of the dimensions of the two paths is the inverse of the ratio of their masses.<\/p>\n<div id=\"fs-id1168326764113\" class=\"media-2\">\n<p id=\"fs-id1168326791026\">You can see an animation of two interacting objects at the <em>My Solar System<\/em> page at <a href=\"https:\/\/openstaxcollege.org\/l\/21mysolarsys\">Phet<\/a>. Choose the Sun and Planet preset option. You can also view the more complicated multiple body problems as well. You may find the actual path of the Moon quite surprising, yet is obeying Newton\u2019s simple laws of motion.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168329317392\">\n<h3>Orbital Transfers<\/h3>\n<p id=\"fs-id1168326841577\">People have imagined traveling to the other planets of our solar system since they were discovered. But how can we best do this? The most efficient method was discovered in 1925 by Walter Hohmann, inspired by a popular science fiction novel of that time. The method is now called a <span class=\"no-emphasis\">Hohmann transfer<\/span>. For the case of traveling between two circular orbits, the transfer is along a \u201ctransfer\u201d ellipse that perfectly intercepts those orbits at the aphelion and perihelion of the ellipse. <a href=\"#CNX_UPhysics_13_05_transfer\" class=\"autogenerated-content\">(Figure)<\/a> shows the case for a trip from Earth\u2019s orbit to that of Mars. As before, the Sun is at the focus of the ellipse.<\/p>\n<p id=\"fs-id1168326846440\">For any ellipse, the semi-major axis is defined as one-half the sum of the perihelion and the aphelion. In <a href=\"#CNX_UPhysics_13_05_conic1\" class=\"autogenerated-content\">(Figure)<\/a>, the semi-major axis is the distance from the origin to either side of the ellipse along the <em>x<\/em>-axis, or just one-half the longest axis (called the major axis). Hence, to travel from one circular orbit of radius [latex]{r}_{1}[\/latex] to another circular orbit of radius [latex]{r}_{2}[\/latex], the aphelion of the transfer ellipse will be equal to the value of the larger orbit, while the perihelion will be the smaller orbit. The semi-major axis, denoted <em>a<\/em>, is therefore given by [latex]a=\\frac{1}{2}\\left({r}_{1}+{r}_{2}\\right)[\/latex].<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_transfer\">\n<div class=\"bc-figcaption figcaption\">The transfer ellipse has its perihelion at Earth\u2019s orbit and aphelion at Mars\u2019 orbit.<\/div>\n<p><span id=\"fs-id1168329105499\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_transfer.jpg\" alt=\"An illustration of the sun and three orbits around it are shown. All three orbits are circular. The innermost orbit is centered on the sun and is labeled Earth Orbit. The middle orbit is not centered on the sun. It coincides with the earth orbit at a point labeled \u201cLaunch\u201d to the right of the sun. An arrow indicates the launch is up and left. The diameter of the orbit is labeled as being a distance 2 a and is shown from the launch point on the right to a point labeled \u201cArrival at Mars\u201d on the left. The sun lies on this diameter. The outermost orbit is centered on the sun and is labeled Mars orbit. This orbit coincides with the middle orbit at the point marked as \u201cArrival at Mars.\u201d A point in the second quadrant (located clockwise from the arrival point) is labeled Mars\u2019 position at launch.\"><\/span><\/p><\/div>\n<p id=\"fs-id1168326783038\">Let\u2019s take the case of traveling from Earth to Mars. For the moment, we ignore the planets and assume we are alone in Earth\u2019s orbit and wish to move to Mars\u2019 orbit. From <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327925427\" class=\"autogenerated-content\">(Figure)<\/a>, the expression for total energy, we can see that the total energy for a spacecraft in the larger orbit (Mars) is greater (less negative) than that for the smaller orbit (Earth). To move onto the transfer ellipse from Earth\u2019s orbit, we will need to increase our kinetic energy, that is, we need a velocity boost. The most efficient method is a very quick acceleration along the circular orbital path, which is also along the path of the ellipse at that point. (In fact, the acceleration should be instantaneous, such that the circular and elliptical orbits are congruent during the acceleration. In practice, the finite acceleration is short enough that the difference is not a significant consideration.) Once you have arrived at Mars orbit, you will need another velocity boost to move into that orbit, or you will stay on the elliptical orbit and simply fall back to perihelion where you started. For the return trip, you simply reverse the process with a retro-boost at each transfer point.<\/p>\n<p id=\"fs-id1168329011316\">To make the move onto the transfer ellipse and then off again, we need to know each circular orbit velocity and the transfer orbit velocities at perihelion and aphelion. The velocity boost required is simply the difference between the circular orbit velocity and the elliptical orbit velocity at each point. We can find the circular orbital velocities from <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168328256234\" class=\"autogenerated-content\">(Figure)<\/a>. To determine the velocities for the ellipse, we state without proof (as it is beyond the scope of this course) that total energy for an elliptical orbit is<\/p>\n<div id=\"fs-id1168056073584\" class=\"unnumbered\">[latex]E=-\\frac{Gm{M}_{\\text{S}}}{2a}[\/latex]<\/div>\n<p id=\"fs-id1168329292060\">where [latex]{M}_{\\text{S}}[\/latex] is the mass of the Sun and <em>a<\/em> is the semi-major axis. Remarkably, this is the same as <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327925427\" class=\"autogenerated-content\">(Figure)<\/a> for circular orbits, but with the value of the semi-major axis replacing the orbital radius. Since we know the potential energy from <a href=\"\/contents\/0103ee2d-bb14-4373-9c21-266f263f500f#fs-id1168329108070\" class=\"autogenerated-content\">(Figure)<\/a>, we can find the kinetic energy and hence the velocity needed for each point on the ellipse. We leave it as a challenge problem to find those transfer velocities for an Earth-to-Mars trip.<\/p>\n<p id=\"fs-id1168329183770\">We end this discussion by pointing out a few important details. First, we have not accounted for the gravitational potential energy due to Earth and Mars, or the mechanics of landing on Mars. In practice, that must be part of the calculations. Second, timing is everything. You do not want to arrive at the orbit of Mars to find out it isn\u2019t there. We must leave Earth at precisely the correct time such that Mars will be at the aphelion of our transfer ellipse just as we arrive. That opportunity comes about every 2 years. And returning requires correct timing as well. The total trip would take just under 3 years! There are other options that provide for a faster transit, including a gravity assist flyby of Venus. But these other options come with an additional cost in energy and danger to the astronauts.<\/p>\n<div id=\"fs-id1168329182768\" class=\"media-2\">\n<p id=\"fs-id1168329516298\">Visit this <a href=\"https:\/\/openstaxcollege.org\/l\/21plantripmars\">site<\/a> for more details about planning a trip to Mars.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168329125485\">\n<h3>Kepler\u2019s Second Law<\/h3>\n<p id=\"fs-id1168329145162\"><span>Kepler\u2019s second law<\/span> states that a planet sweeps out equal areas in equal times, that is, the area divided by time, called the areal velocity, is constant. Consider <a href=\"#CNX_UPhysics_13_05_Keplers2nd\" class=\"autogenerated-content\">(Figure)<\/a>. The time it takes a planet to move from position <em>A<\/em> to <em>B<\/em>, sweeping out area [latex]{A}_{1}[\/latex], is exactly the time taken to move from position <em>C<\/em> to <em>D<\/em>, sweeping area [latex]{A}_{2}[\/latex], and to move from <em>E<\/em> to <em>F<\/em>, sweeping out area [latex]{A}_{3}[\/latex]. These areas are the same: [latex]{A}_{1}={A}_{2}={A}_{3}[\/latex].<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_Keplers2nd\">\n<div class=\"bc-figcaption figcaption\">The shaded regions shown have equal areas and represent the same time interval.<\/div>\n<p><span id=\"fs-id1168329048142\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_Keplers2nd.jpg\" alt=\"An x y coordinate system is shown with the sun, also labeled as M, on the x axis to the left of the origin and an unlabeled point to the right of the origin. A planet, labeled also as m, is shown in the second quadrant. An arrow, labeled v, extends from the planet and points down and left, tangent to the orbit. Points A, B, C, D, E, and F are labeled on the orbit. Points A and B are in the third quadrant. The area of the region defined by A B and the sun is labeled A 1. Points C and D are in on the orbit on either side of the \u2013 y axis. The area of the region defined by C D and the sun is labeled A 2. Points E and F are in the first quadrant. The area of the region defined by E F and the sun is labeled A 3. The pair of points A B have the largest distance between them and is closest to the sun. E F have the smallest distance between them and are farthest from the sun.\"><\/span><\/p><\/div>\n<p id=\"fs-id1168329063875\">Comparing the areas in the figure and the distance traveled along the ellipse in each case, we can see that in order for the areas to be equal, the planet must speed up as it gets closer to the Sun and slow down as it moves away. This behavior is completely consistent with our conservation equation, <a href=\"\/contents\/0103ee2d-bb14-4373-9c21-266f263f500f#fs-id1168326928404\" class=\"autogenerated-content\">(Figure)<\/a>. But we will show that Kepler\u2019s second law is actually a consequence of the conservation of angular momentum, which holds for any system with only radial forces.<\/p>\n<p id=\"fs-id1168329061906\">Recall the definition of angular momentum from <a href=\"\/contents\/3725769f-b3aa-424e-9d7b-a0ef8e6b0d19\" class=\"target-chapter\">Angular Momentum<\/a>, [latex]\\stackrel{\\to }{L}=\\stackrel{\\to }{r}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}\\stackrel{\\to }{p}[\/latex]. For the case of orbiting motion, [latex]\\stackrel{\\to }{L}[\/latex] is the angular momentum of the planet about the Sun, [latex]\\stackrel{\\to }{r}[\/latex] is the position vector of the planet measured from the Sun, and [latex]\\stackrel{\\to }{p}=m\\stackrel{\\to }{v}[\/latex] is the instantaneous linear momentum at any point in the orbit. Since the planet moves along the ellipse, [latex]\\stackrel{\\to }{p}[\/latex] is always tangent to the ellipse.<\/p>\n<p id=\"fs-id1168329020269\">We can resolve the linear momentum into two components: a radial component [latex]{\\stackrel{\\to }{p}}_{\\text{rad}}[\/latex] along the line to the Sun, and a component [latex]{\\stackrel{\\to }{p}}_{\\text{perp}}[\/latex] perpendicular to [latex]\\stackrel{\\to }{r}[\/latex]. The cross product for angular momentum can then be written as<\/p>\n<p id=\"fs-id1168329395013\">[latex]\\stackrel{\\to }{L}=\\stackrel{\\to }{r}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}\\stackrel{\\to }{p}=\\stackrel{\\to }{r}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}\\left({\\stackrel{\\to }{p}}_{\\text{rad}}+{\\stackrel{\\to }{p}}_{\\text{perp}}\\right)=\\stackrel{\\to }{r}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{\\stackrel{\\to }{p}}_{\\text{rad}}+\\stackrel{\\to }{r}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{\\stackrel{\\to }{p}}_{\\text{perp}}[\/latex].<\/p>\n<p id=\"fs-id1168329169523\">The first term on the right is zero because [latex]\\stackrel{\\to }{r}[\/latex] is parallel to [latex]{\\stackrel{\\to }{p}}_{\\text{rad}}[\/latex], and in the second term [latex]\\stackrel{\\to }{r}[\/latex] is perpendicular to [latex]{\\stackrel{\\to }{p}}_{\\text{perp}}[\/latex], so the magnitude of the cross product reduces to [latex]L=r{p}_{\\text{perp}}=rm{v}_{\\text{perp}}[\/latex]. Note that the angular momentum does <em>not<\/em> depend upon [latex]{p}_{\\text{rad}}[\/latex]. Since the gravitational force is only in the radial direction, it can change only [latex]{p}_{\\text{rad}}[\/latex] and not [latex]{p}_{\\text{perp}}[\/latex]; hence, the angular momentum must remain constant.<\/p>\n<p id=\"fs-id1168329182115\">Now consider <a href=\"#CNX_UPhysics_13_05_area\" class=\"autogenerated-content\">(Figure)<\/a>. A small triangular area [latex]\\text{\u0394}A[\/latex] is swept out in time [latex]\\text{\u0394}t[\/latex]. The velocity is along the path and it makes an angle [latex]\\theta [\/latex] with the radial direction. Hence, the perpendicular velocity is given by [latex]{v}_{\\text{perp}}=v\\text{sin}\\theta [\/latex]. The planet moves a distance [latex]\\text{\u0394}s=v\\text{\u0394}t\\text{sin}\\theta [\/latex] projected along the direction perpendicular to <em>r<\/em>. Since the area of a triangle is one-half the base (<em>r<\/em>) times the height [latex]\\left(\\text{\u0394}s\\right)[\/latex], for a small displacement, the area is given by [latex]\\text{\u0394}A=\\frac{1}{2}r\\text{\u0394}s[\/latex]. Substituting for [latex]\\text{\u0394}s[\/latex], multiplying by <em>m<\/em> in the numerator and denominator, and rearranging, we obtain<\/p>\n<div id=\"fs-id1168056237254\" class=\"unnumbered\">[latex]\\text{\u0394}A=\\frac{1}{2}r\\text{\u0394}s=\\frac{1}{2}r\\left(v\\text{\u0394}t\\text{sin}\\theta \\right)=\\frac{1}{2m}r\\left(mv\\text{sin}\\theta \\text{\u0394}t\\right)=\\frac{1}{2m}r\\left(m{v}_{\\text{perp}}\\text{\u0394}t\\right)=\\frac{L}{2m}\\text{\u0394}t.[\/latex]<\/div>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_area\">\n<div class=\"bc-figcaption figcaption\">The element of area [latex]\\text{\u0394}A[\/latex] swept out in time [latex]\\text{\u0394}t[\/latex] as the planet moves through angle [latex]\\text{\u0394}\\varphi [\/latex]. The angle between the radial direction and [latex]\\stackrel{\\to }{v}[\/latex] is [latex]\\theta [\/latex].<\/div>\n<p><span id=\"fs-id1168326918024\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_area.jpg\" alt=\"A diagram showing the sun and a planet separated by a distance r. The velocity vector of the planet is shown as an arrow pointing at an obtuse angle to the distance r between the sun and planet. The line connecting the sun and planet is extended past the planet as a dashed line, and another dashed line is drawn from the tip of the velocity arrow to the dashed extension of r. The dashed lines meet at a right angle and form a triangle with the velocity arrow forming the hypotenuse and the planet at one vertex. The angle near the planet is labeled theta. The hypotenuse is also labeled v delta t, and the side opposite the planet labeled v delta t sin theta. The triangular region defined by the sun, planet and the tip of the velocity arrow is labeled Delta A, and the angle near the sun is labeled delta phi.\"><\/span><\/p><\/div>\n<p id=\"fs-id1168329292326\">The areal velocity is simply the rate of change of area with time, so we have<\/p>\n<div id=\"fs-id1168056552111\" class=\"unnumbered\">[latex]\\text{areal velocity}=\\phantom{\\rule{0.2em}{0ex}}\\frac{\\text{\u0394}A}{\\text{\u0394}t}=\\frac{L}{2m}.[\/latex]<\/div>\n<p id=\"fs-id1168326792738\">Since the angular momentum is constant, the areal velocity must also be constant. This is exactly Kepler\u2019s second law. As with Kepler\u2019s first law, Newton showed it was a natural consequence of his law of gravitation.<\/p>\n<div id=\"fs-id1168326861426\" class=\"media-2\">\n<p id=\"fs-id1168329266256\">You can view an <a href=\"https:\/\/openstaxcollege.org\/l\/21animationgrav\">animated version<\/a> of <a href=\"#CNX_UPhysics_13_05_Keplers2nd\" class=\"autogenerated-content\">(Figure)<\/a>, and many other interesting animations as well, at the School of Physics (University of New South Wales) site.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168326781140\">\n<h3>Kepler\u2019s Third Law<\/h3>\n<p id=\"fs-id1168329503239\"><span>Kepler\u2019s third law<\/span> states that the square of the period is proportional to the cube of the semi-major axis of the orbit. In <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25\" class=\"target-chapter\">Satellite Orbits and Energy<\/a>, we derived Kepler\u2019s third law for the special case of a circular orbit. <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> gives us the period of a circular orbit of radius <em>r<\/em> about Earth:<\/p>\n<div id=\"fs-id1168056224278\" class=\"unnumbered\">[latex]T=2\\pi \\sqrt{\\frac{{r}^{3}}{G{M}_{\\text{E}}}}.[\/latex]<\/div>\n<p id=\"fs-id1168327143853\">For an ellipse, recall that the semi-major axis is one-half the sum of the perihelion and the aphelion. For a circular orbit, the semi-major axis (<em>a<\/em>) is the same as the radius for the orbit. In fact, <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> gives us Kepler\u2019s third law if we simply replace <em>r<\/em> with <em>a<\/em> and square both sides.<\/p>\n<div id=\"fs-id1168326821418\" class=\"equation-callout\">\n<div id=\"fs-id1168329126738\">[latex]{T}^{2}=\\frac{4{\\pi }^{2}}{GM}{a}^{3}[\/latex]<\/div>\n<\/div>\n<p id=\"fs-id1168329191321\">We have changed the mass of Earth to the more general <em>M<\/em>, since this equation applies to satellites orbiting any large mass.<\/p>\n<div id=\"fs-id1168326766432\" class=\"textbox examples\">\n<p id=\"fs-id1168329517500\"><span>Orbit of Halley\u2019s Comet<\/span><br>\nDetermine the semi-major axis of the orbit of <span class=\"no-emphasis\">Halley\u2019s comet<\/span>, given that it arrives at perihelion every 75.3 years. If the perihelion is 0.586 AU, what is the aphelion?<\/p>\n<p id=\"fs-id1168326787614\"><span>Strategy<\/span><br>\nWe are given the period, so we can rearrange <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a>, solving for the semi-major axis. Since we know the value for the perihelion, we can use the definition of the semi-major axis, given earlier in this section, to find the aphelion. We note that 1 Astronomical Unit (AU) is the average radius of Earth\u2019s orbit and is defined to be [latex]1\\phantom{\\rule{0.2em}{0ex}}\\text{AU}=1.50\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{11}\\phantom{\\rule{0.2em}{0ex}}\\text{m}[\/latex].<\/p>\n<p id=\"fs-id1168326764458\"><span>Solution<\/span><br>\nRearranging <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a> and inserting the values of the period of Halley\u2019s comet and the mass of the Sun, we have<\/p>\n<div id=\"fs-id1168056579806\" class=\"unnumbered\">[latex]\\begin{array}{}\\\\ \\hfill a&amp; ={\\left(\\frac{GM}{4{\\pi }^{2}}{T}^{2}\\right)}^{1\\text{\/}3}\\hfill \\\\ &amp; ={\\left(\\frac{\\left(6.67\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{-11}\\phantom{\\rule{0.2em}{0ex}}\\text{N}\u00b7{\\text{m}}^{2}{\\text{\/kg}}^{2}\\right)\\left(2.00\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{30}\\phantom{\\rule{0.2em}{0ex}}\\text{kg}\\right)}{4{\\pi }^{2}}{\\left(75.3\\phantom{\\rule{0.2em}{0ex}}\\text{yr}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}365\\phantom{\\rule{0.2em}{0ex}}\\text{days\/yr}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}24\\phantom{\\rule{0.2em}{0ex}}\\text{hr\/day}\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}3600\\phantom{\\rule{0.2em}{0ex}}\\text{s\/hr}\\right)}^{2}\\right)}^{1\\text{\/}3}.\\hfill \\end{array}[\/latex]<\/div>\n<p id=\"fs-id1168329173624\">This yields a value of [latex]2.67\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{12}\\phantom{\\rule{0.2em}{0ex}}\\text{m}[\/latex] or 17.8 AU for the semi-major axis.<\/p>\n<p id=\"fs-id1168329041363\">The semi-major axis is one-half the sum of the aphelion and perihelion, so we have<\/p>\n<div id=\"fs-id1168056151854\" class=\"unnumbered\">[latex]\\begin{array}{}\\\\ \\hfill a&amp; =\\hfill &amp; \\frac{1}{2}\\left(\\text{aphelion}+\\text{perihelion}\\right)\\hfill \\\\ \\hfill \\text{aphelion}&amp; =\\hfill &amp; 2a-\\text{perihelion}.\\hfill \\end{array}[\/latex]<\/div>\n<p id=\"fs-id1168327144713\">Substituting for the values, we found for the semi-major axis and the value given for the perihelion, we find the value of the aphelion to be 35.0 AU.<\/p>\n<p id=\"fs-id1168329518634\"><span>Significance<\/span><br>\nEdmond <span class=\"no-emphasis\">Halley<\/span>, a contemporary of Newton, first suspected that three comets, reported in 1531, 1607, and 1682, were actually the same comet. Before Tycho Brahe made measurements of comets, it was believed that they were one-time events, perhaps disturbances in the atmosphere, and that they were not affected by the Sun. Halley used Newton\u2019s new mechanics to predict his namesake comet\u2019s return in 1758.<\/p>\n<\/div>\n<div id=\"fs-id1168326788503\" class=\"check-understanding\">\n<div id=\"fs-id1168329171728\">\n<div id=\"fs-id1168326855597\">\n<p id=\"fs-id1168329511181\"><strong>Check Your Understanding<\/strong> The nearly circular orbit of Saturn has an average radius of about 9.5 AU and has a period of 30 years, whereas Uranus averages about 19 AU and has a period of 84 years. Is this consistent with our results for Halley\u2019s comet?<\/p>\n<\/div>\n<div id=\"fs-id1168326822487\">\n<p id=\"fs-id1168329148442\">The semi-major axis for the highly elliptical orbit of Halley\u2019s comet is 17.8 AU and is the average of the perihelion and aphelion. This lies between the 9.5 AU and 19 AU orbital radii for Saturn and Uranus, respectively. The radius for a circular orbit is the same as the semi-major axis, and since the period increases with an increase of the semi-major axis, the fact that Halley\u2019s period is between the periods of Saturn and Uranus is expected.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"textbox key-takeaways\" id=\"fs-id1168326765523\">\n<h3>Summary<\/h3>\n<ul id=\"fs-id1168327054984\">\n<li>All orbital motion follows the path of a conic section. Bound or closed orbits are either a circle or an ellipse; unbounded or open orbits are either a parabola or a hyperbola.<\/li>\n<li>The areal velocity of any orbit is constant, a reflection of the conservation of angular momentum.<\/li>\n<li>The square of the period of an elliptical orbit is proportional to the cube of the semi-major axis of that orbit.<\/li>\n<\/ul>\n<\/div>\n<div class=\"review-conceptual-questions\" id=\"fs-id1168329320256\">\n<h3>Conceptual Questions<\/h3>\n<div id=\"fs-id1168329160078\">\n<div id=\"fs-id1168329340846\">\n<p id=\"fs-id1168326763270\">Are Kepler\u2019s laws purely descriptive, or do they contain causal information?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329332078\">\n<div id=\"fs-id1168326777238\">\n<p id=\"fs-id1168329130138\">In the diagram below for a satellite in an elliptical orbit about a much larger mass, indicate where its speed is the greatest and where it is the least. What conservation law dictates this behavior? Indicate the directions of the force, acceleration, and velocity at these points. Draw vectors for these same three quantities at the two points where the <em>y<\/em>-axis intersects (along the semi-minor axis) and from this determine whether the speed is increasing decreasing, or at a max\/min.<\/p>\n<p><span id=\"fs-id1168326759021\"><img src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_P65_img.jpg\" alt=\"A diagram showing an x y coordinate system and an ellipse, centered on the origin with foci on the x axis. The focus on the left is labeled f 1 and M. The focus on the right is labeled f 2. A location labeled as m is shown above f 2. The right triangle defined by f 1, f 2, and m is shown in red. The clockwise direction tangent to the ellipse is indicated by blue arrows.\"><\/span><\/p><\/div>\n<div id=\"fs-id1168329187953\">\n<p id=\"fs-id1168329191139\">The speed is greatest where the satellite is closest to the large mass and least where farther away\u2014at the periapsis and apoapsis, respectively. It is conservation of angular momentum that governs this relationship. But it can also be gleaned from conservation of energy, the kinetic energy must be greatest where the gravitational potential energy is the least (most negative). The force, and hence acceleration, is always directed towards <em>M<\/em> in the diagram, and the velocity is always tangent to the path at all points. The acceleration vector has a tangential component along the direction of the velocity at the upper location on the <em>y<\/em>-axis; hence, the satellite is speeding up. Just the opposite is true at the lower position.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"review-problems\" id=\"fs-id1168326822588\">\n<h3>Problems<\/h3>\n<div id=\"fs-id1168329105797\">\n<div id=\"fs-id1168329022150\">\n<p id=\"fs-id1168329519026\">Calculate the mass of the Sun based on data for average Earth\u2019s orbit and compare the value obtained with the Sun\u2019s commonly listed value of [latex]1.989\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{30}\\phantom{\\rule{0.2em}{0ex}}\\text{kg}[\/latex].<\/p>\n<\/div>\n<div>\n<p id=\"fs-id1168329450483\">[latex]1.98\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{30}\\phantom{\\rule{0.2em}{0ex}}\\text{kg}[\/latex]; The values are the same within 0.05%.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329194156\">\n<div id=\"fs-id1168329083138\">\n<p id=\"fs-id1168326842605\">Io orbits Jupiter with an average radius of 421,700 km and a period of 1.769 days. Based upon these data, what is the mass of Jupiter?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168326926286\">\n<div id=\"fs-id1168329443467\">\n<p id=\"fs-id1168329156360\">The \u201cmean\u201d orbital radius listed for astronomical objects orbiting the Sun is typically not an integrated average but is calculated such that it gives the correct period when applied to the equation for circular orbits. Given that, what is the mean orbital radius in terms of aphelion and perihelion?<\/p>\n<\/div>\n<div id=\"fs-id1168329510821\">\n<p id=\"fs-id1168329107484\">Compare <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> and <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a> to see that they differ only in that the circular radius, <em>r<\/em>, is replaced by the semi-major axis, <em>a<\/em>. Therefore, the mean radius is one-half the sum of the aphelion and perihelion, the same as the semi-major axis.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329196621\">\n<div id=\"fs-id1168329184371\">\n<p id=\"fs-id1168329264997\">The perihelion of Halley\u2019s comet is 0.586 AU and the aphelion is 17.8 AU. Given that its speed at perihelion is 55 km\/s, what is the speed at aphelion ([latex]1\\phantom{\\rule{0.2em}{0ex}}\\text{AU}=1.496\\phantom{\\rule{0.2em}{0ex}}\u00d7\\phantom{\\rule{0.2em}{0ex}}{10}^{11}\\phantom{\\rule{0.2em}{0ex}}\\text{m}[\/latex])? (<em>Hint:<\/em> You may use either conservation of energy or angular momentum, but the latter is much easier.)<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329319495\">\n<div id=\"fs-id1168326792076\">\n<p id=\"fs-id1168326857947\">The perihelion of the comet Lagerkvist is 2.61 AU and it has a period of 7.36 years. Show that the aphelion for this comet is 4.95 AU.<\/p>\n<\/div>\n<div id=\"fs-id1168329148430\">\n<p id=\"fs-id1168329169186\">The semi-major axis, 3.78 AU is found from the equation for the period. This is one-half the sum of the aphelion and perihelion, giving an aphelion distance of 4.95 AU.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168326939686\">\n<div id=\"fs-id1168329071274\">\n<p id=\"fs-id1168329055659\">What is the ratio of the speed at perihelion to that at aphelion for the comet Lagerkvist in the previous problem?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329151836\">\n<div id=\"fs-id1168329047827\">\n<p id=\"fs-id1168329061232\">Eros has an elliptical orbit about the Sun, with a perihelion distance of 1.13 AU and aphelion distance of 1.78 AU. What is the period of its orbit?<\/p>\n<\/div>\n<div id=\"fs-id1168329181708\">\n<p id=\"fs-id1168329064510\">1.75 years<\/p>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"textbox shaded\">\n<h3>Glossary<\/h3>\n<dl id=\"fs-id1168329331558\">\n<dt>aphelion<\/dt>\n<dd id=\"fs-id1168326837993\">farthest point from the Sun of an orbiting body; the corresponding term for the Moon\u2019s farthest point from Earth is the apogee<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329517229\">\n<dt>Kepler\u2019s first law<\/dt>\n<dd id=\"fs-id1168326765861\">law stating that every planet moves along an ellipse, with the Sun located at a focus of the ellipse<\/dd>\n<\/dl>\n<dl id=\"fs-id1168326790250\">\n<dt>Kepler\u2019s second law<\/dt>\n<dd id=\"fs-id1168329461373\">law stating that a planet sweeps out equal areas in equal times, meaning it has a constant areal velocity<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329137868\">\n<dt>Kepler\u2019s third law<\/dt>\n<dd id=\"fs-id1168329188942\">law stating that the square of the period is proportional to the cube of the semi-major axis of the orbit<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329454958\">\n<dt>perihelion<\/dt>\n<dd id=\"fs-id1168326778106\">point of closest approach to the Sun of an orbiting body; the corresponding term for the Moon\u2019s closest approach to Earth is the perigee<\/dd>\n<\/dl>\n<\/div>\n\n","rendered":"<div class=\"textbox learning-objectives\">\n<h3>Learning Objectives<\/h3>\n<p>By the end of this section, you will be able to:<\/p>\n<ul>\n<li>Describe the conic sections and how they relate to orbital motion<\/li>\n<li>Describe how orbital velocity is related to conservation of angular momentum<\/li>\n<li>Determine the period of an elliptical orbit from its major axis<\/li>\n<\/ul>\n<\/div>\n<p id=\"fs-id1168329287987\">Using the precise data collected by Tycho Brahe, Johannes Kepler carefully analyzed the positions in the sky of all the known planets and the Moon, plotting their positions at regular intervals of time. From this analysis, he formulated three laws, which we address in this section.<\/p>\n<div class=\"bc-section section\" id=\"fs-id1168329183887\">\n<h3>Kepler\u2019s First Law<\/h3>\n<p>The prevailing view during the time of Kepler was that all planetary orbits were circular. The data for Mars presented the greatest challenge to this view and that eventually encouraged Kepler to give up the popular idea. <span>Kepler\u2019s first law<\/span> states that every planet moves along an ellipse, with the Sun located at a focus of the ellipse. An ellipse is defined as the set of all points such that the sum of the distance from each point to two foci is a constant. <a href=\"#CNX_UPhysics_13_05_Ellipse\" class=\"autogenerated-content\">(Figure)<\/a> shows an ellipse and describes a simple way to create it.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_Ellipse\">\n<div class=\"bc-figcaption figcaption\">(a) An ellipse is a curve in which the sum of the distances from a point on the curve to two foci <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-33a0e456da9a841ddfcd025c69cca076_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#108;&#101;&#102;&#116;&#40;&#123;&#102;&#125;&#95;&#123;&#49;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#97;&#110;&#100;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#102;&#125;&#95;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"80\" style=\"vertical-align: -4px;\" \/> is a constant. From this definition, you can see that an ellipse can be created in the following way. Place a pin at each focus, then place a loop of string around a pencil and the pins. Keeping the string taught, move the pencil around in a complete circuit. If the two foci occupy the same place, the result is a circle\u2014a special case of an ellipse. (b) For an elliptical orbit, if <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-805890d5cb68a2592b48ca23f65a0d4f_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#109;&#92;&#108;&#108;&#32;&#77;\" title=\"Rendered by QuickLaTeX.com\" height=\"14\" width=\"62\" style=\"vertical-align: -2px;\" \/>, then <em>m<\/em> follows an elliptical path with <em>M<\/em> at one focus. More exactly, both <em>m<\/em> and <em>M<\/em> move in their own ellipse about the common center of mass.<\/div>\n<p><span id=\"fs-id1168327148139\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_Ellipse.jpg\" alt=\"Figure a shows an x y coordinate system and an ellipse centered on the origin with foci f 1 on the left and f 2 on the right, both on the x axis. Focus f 1 is also labeled M. A point above focus f 2 is labeled m. The right triangle formed by f 1, f 2, and m is shown in red. Figure b shows a similar ellipse, with the sun shown and labeled as M and as Sun at f 1. A planet mass m is shown above f 1, at a vertical distance r from f 1. The location where the ellipse intersects the horizontal axis on the left is labeled as point A, and the location where the ellipse intersects the horizontal axis on the right is labeled as point B.\" \/><\/span><\/p>\n<\/div>\n<p id=\"fs-id1168329179515\">For elliptical orbits, the point of closest approach of a planet to the Sun is called the <span>perihelion<\/span>. It is labeled point <em>A<\/em> in <a href=\"#CNX_UPhysics_13_05_Ellipse\" class=\"autogenerated-content\">(Figure)<\/a>. The farthest point is the <span>aphelion<\/span> and is labeled point <em>B<\/em> in the figure. For the Moon\u2019s orbit about Earth, those points are called the perigee and apogee, respectively.<\/p>\n<p id=\"fs-id1168329288308\">An ellipse has several mathematical forms, but all are a specific case of the more general equation for conic sections. There are four different conic sections, all given by the equation<\/p>\n<div id=\"fs-id1168329125888\" class=\"equation-callout\">\n<div><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-e8f7ccfd7788744648e54f3eae4d5700_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#102;&#114;&#97;&#99;&#123;&#92;&#97;&#108;&#112;&#104;&#97;&#32;&#125;&#123;&#114;&#125;&#61;&#49;&#43;&#101;&#92;&#116;&#101;&#120;&#116;&#123;&#99;&#111;&#115;&#125;&#92;&#116;&#104;&#101;&#116;&#97;&#32;&#46;\" title=\"Rendered by QuickLaTeX.com\" height=\"19\" width=\"110\" style=\"vertical-align: -6px;\" \/><\/div>\n<\/div>\n<p id=\"fs-id1168327081841\">The variables <em>r<\/em> and <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-761998727948942ceb1b5763e45f01e4_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"9\" style=\"vertical-align: 0px;\" \/> are shown in <a href=\"#CNX_UPhysics_13_05_conic1\" class=\"autogenerated-content\">(Figure)<\/a> in the case of an ellipse. The constants <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-946f8144d4e3d460c8621773145884d3_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#97;&#108;&#112;&#104;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"8\" width=\"11\" style=\"vertical-align: 0px;\" \/> and <em>e<\/em> are determined by the total energy and angular momentum of the satellite at a given point. The constant <em>e<\/em> is called the eccentricity. The values of <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-946f8144d4e3d460c8621773145884d3_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#97;&#108;&#112;&#104;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"8\" width=\"11\" style=\"vertical-align: 0px;\" \/> and <em>e<\/em> determine which of the four conic sections represents the path of the satellite.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_conic1\">\n<div class=\"bc-figcaption figcaption\">As before, the distance between the planet and the Sun is <em>r<\/em>, and the angle measured from the <em>x<\/em>-axis, which is along the major axis of the ellipse, is <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-761998727948942ceb1b5763e45f01e4_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"9\" style=\"vertical-align: 0px;\" \/>.<\/div>\n<p><span id=\"fs-id1168326938983\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_conic1.jpg\" alt=\"An x y coordinate system and an ellipse centered on the origin with foci f 1 on the left and f 2 on the right, both on the x axis, are shown. Focus f 1 is also labeled M. A point on the ellipse in the first quadrant is labeled m. The horizontal segment connecting the foci f 1 and f 2, and the segment connecting f 1 and m are shown in red. The angle between those segments is labeled Theta.\" \/><\/span><\/p>\n<\/div>\n<p id=\"fs-id1168326747212\">One of the real triumphs of Newton\u2019s law of universal gravitation, with the force proportional to the inverse of the distance squared, is that when it is combined with his second law, the solution for the path of any satellite is a conic section. Every path taken by <em>m<\/em> is one of the four conic sections: a circle or an ellipse for bound or closed orbits, or a parabola or hyperbola for unbounded or open orbits. These conic sections are shown in <a href=\"#CNX_UPhysics_13_05_conic2\" class=\"autogenerated-content\">(Figure)<\/a>.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_conic2\">\n<div class=\"bc-figcaption figcaption\">All motion caused by an inverse square force is one of the four conic sections and is determined by the energy and direction of the moving body.<\/div>\n<p><span id=\"fs-id1168329254205\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_conic2.jpg\" alt=\"A cone and its conic sections is shown. At the top a horizontal cut is shaded and a dashed line shown across the shading. This section is labeled circle. Below this a diagonal cut and line are shown. The line and cut intersect the sides of the cone. This section is labeled ellipse. Next is a diagonal cut and line that intersect the sides and the bottom of the cone and are labeled parabola. The last section is a vertical line and shaded cut labeled hyperbola\" \/><\/span><\/p>\n<\/div>\n<p>If the total energy is negative, then <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-5ca0183a1896859077499dcaf1337464_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#48;&#92;&#108;&#101;&#32;&#101;&#60;&#49;\" title=\"Rendered by QuickLaTeX.com\" height=\"15\" width=\"72\" style=\"vertical-align: -3px;\" \/>, and <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> represents a bound or closed orbit of either an ellipse or a circle, where <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-9beb59bf1cf9478ab2576f0790ba25c1_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#101;&#61;&#48;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"41\" style=\"vertical-align: 0px;\" \/>. [You can see from <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> that for <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-9beb59bf1cf9478ab2576f0790ba25c1_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#101;&#61;&#48;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"41\" style=\"vertical-align: 0px;\" \/>, <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-318ea623440f567a3d7e4cfa4aee7ef9_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#114;&#61;&#92;&#97;&#108;&#112;&#104;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"8\" width=\"43\" style=\"vertical-align: 0px;\" \/>, and hence the radius is constant.] For ellipses, the eccentricity is related to how oblong the ellipse appears. A circle has zero eccentricity, whereas a very long, drawn-out ellipse has an eccentricity near one.<\/p>\n<p id=\"fs-id1168329193027\">If the total energy is exactly zero, then <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-24cd40802af9668cd45601e5567f187f_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#101;&#61;&#49;\" title=\"Rendered by QuickLaTeX.com\" height=\"13\" width=\"40\" style=\"vertical-align: -1px;\" \/> and the path is a parabola. Recall that a satellite with zero total energy has exactly the escape velocity. (The parabola is formed only by slicing the cone parallel to the tangent line along the surface.) Finally, if the total energy is positive, then <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-47a5ae71a1f4a771f6017b1fc5600ec4_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#101;&#62;&#49;\" title=\"Rendered by QuickLaTeX.com\" height=\"13\" width=\"40\" style=\"vertical-align: -1px;\" \/> and the path is a hyperbola. These last two paths represent unbounded orbits, where <em>m<\/em> passes by <em>M<\/em> once and only once. This situation has been observed for several comets that approach the Sun and then travel away, never to return.<\/p>\n<p>We have confined ourselves to the case in which the smaller mass (planet) orbits a much larger, and hence stationary, mass (Sun), but <a href=\"#fs-id1168329150881\" class=\"autogenerated-content\">(Figure)<\/a> also applies to any two gravitationally interacting masses. Each mass traces out the exact same-shaped conic section as the other. That shape is determined by the total energy and angular momentum of the system, with the center of mass of the system located at the focus. The ratio of the dimensions of the two paths is the inverse of the ratio of their masses.<\/p>\n<div id=\"fs-id1168326764113\" class=\"media-2\">\n<p id=\"fs-id1168326791026\">You can see an animation of two interacting objects at the <em>My Solar System<\/em> page at <a href=\"https:\/\/openstaxcollege.org\/l\/21mysolarsys\">Phet<\/a>. Choose the Sun and Planet preset option. You can also view the more complicated multiple body problems as well. You may find the actual path of the Moon quite surprising, yet is obeying Newton\u2019s simple laws of motion.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168329317392\">\n<h3>Orbital Transfers<\/h3>\n<p id=\"fs-id1168326841577\">People have imagined traveling to the other planets of our solar system since they were discovered. But how can we best do this? The most efficient method was discovered in 1925 by Walter Hohmann, inspired by a popular science fiction novel of that time. The method is now called a <span class=\"no-emphasis\">Hohmann transfer<\/span>. For the case of traveling between two circular orbits, the transfer is along a \u201ctransfer\u201d ellipse that perfectly intercepts those orbits at the aphelion and perihelion of the ellipse. <a href=\"#CNX_UPhysics_13_05_transfer\" class=\"autogenerated-content\">(Figure)<\/a> shows the case for a trip from Earth\u2019s orbit to that of Mars. As before, the Sun is at the focus of the ellipse.<\/p>\n<p id=\"fs-id1168326846440\">For any ellipse, the semi-major axis is defined as one-half the sum of the perihelion and the aphelion. In <a href=\"#CNX_UPhysics_13_05_conic1\" class=\"autogenerated-content\">(Figure)<\/a>, the semi-major axis is the distance from the origin to either side of the ellipse along the <em>x<\/em>-axis, or just one-half the longest axis (called the major axis). Hence, to travel from one circular orbit of radius <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-2d385880f8bdc4e3571b9ff8520e509c_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#114;&#125;&#95;&#123;&#49;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"14\" style=\"vertical-align: -4px;\" \/> to another circular orbit of radius <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-f5c4a61d294b4f9a558667e94a87ffac_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#114;&#125;&#95;&#123;&#50;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"11\" width=\"15\" style=\"vertical-align: -3px;\" \/>, the aphelion of the transfer ellipse will be equal to the value of the larger orbit, while the perihelion will be the smaller orbit. The semi-major axis, denoted <em>a<\/em>, is therefore given by <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-8bae88496448b1642aed211c7d849e33_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#97;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;&#92;&#108;&#101;&#102;&#116;&#40;&#123;&#114;&#125;&#95;&#123;&#49;&#125;&#43;&#123;&#114;&#125;&#95;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;\" title=\"Rendered by QuickLaTeX.com\" height=\"22\" width=\"113\" style=\"vertical-align: -6px;\" \/>.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_transfer\">\n<div class=\"bc-figcaption figcaption\">The transfer ellipse has its perihelion at Earth\u2019s orbit and aphelion at Mars\u2019 orbit.<\/div>\n<p><span id=\"fs-id1168329105499\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_transfer.jpg\" alt=\"An illustration of the sun and three orbits around it are shown. All three orbits are circular. The innermost orbit is centered on the sun and is labeled Earth Orbit. The middle orbit is not centered on the sun. It coincides with the earth orbit at a point labeled \u201cLaunch\u201d to the right of the sun. An arrow indicates the launch is up and left. The diameter of the orbit is labeled as being a distance 2 a and is shown from the launch point on the right to a point labeled \u201cArrival at Mars\u201d on the left. The sun lies on this diameter. The outermost orbit is centered on the sun and is labeled Mars orbit. This orbit coincides with the middle orbit at the point marked as \u201cArrival at Mars.\u201d A point in the second quadrant (located clockwise from the arrival point) is labeled Mars\u2019 position at launch.\" \/><\/span><\/p>\n<\/div>\n<p id=\"fs-id1168326783038\">Let\u2019s take the case of traveling from Earth to Mars. For the moment, we ignore the planets and assume we are alone in Earth\u2019s orbit and wish to move to Mars\u2019 orbit. From <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327925427\" class=\"autogenerated-content\">(Figure)<\/a>, the expression for total energy, we can see that the total energy for a spacecraft in the larger orbit (Mars) is greater (less negative) than that for the smaller orbit (Earth). To move onto the transfer ellipse from Earth\u2019s orbit, we will need to increase our kinetic energy, that is, we need a velocity boost. The most efficient method is a very quick acceleration along the circular orbital path, which is also along the path of the ellipse at that point. (In fact, the acceleration should be instantaneous, such that the circular and elliptical orbits are congruent during the acceleration. In practice, the finite acceleration is short enough that the difference is not a significant consideration.) Once you have arrived at Mars orbit, you will need another velocity boost to move into that orbit, or you will stay on the elliptical orbit and simply fall back to perihelion where you started. For the return trip, you simply reverse the process with a retro-boost at each transfer point.<\/p>\n<p id=\"fs-id1168329011316\">To make the move onto the transfer ellipse and then off again, we need to know each circular orbit velocity and the transfer orbit velocities at perihelion and aphelion. The velocity boost required is simply the difference between the circular orbit velocity and the elliptical orbit velocity at each point. We can find the circular orbital velocities from <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168328256234\" class=\"autogenerated-content\">(Figure)<\/a>. To determine the velocities for the ellipse, we state without proof (as it is beyond the scope of this course) that total energy for an elliptical orbit is<\/p>\n<div id=\"fs-id1168056073584\" class=\"unnumbered\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-fcde3f3d103df0d6cdf55385aa2a24c1_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#69;&#61;&#45;&#92;&#102;&#114;&#97;&#99;&#123;&#71;&#109;&#123;&#77;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#83;&#125;&#125;&#125;&#123;&#50;&#97;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"23\" width=\"97\" style=\"vertical-align: -6px;\" \/><\/div>\n<p id=\"fs-id1168329292060\">where <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-4b0f2a30f27d0ae2b4485ff7b5bcd198_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#77;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#83;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"15\" width=\"24\" style=\"vertical-align: -3px;\" \/> is the mass of the Sun and <em>a<\/em> is the semi-major axis. Remarkably, this is the same as <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327925427\" class=\"autogenerated-content\">(Figure)<\/a> for circular orbits, but with the value of the semi-major axis replacing the orbital radius. Since we know the potential energy from <a href=\"\/contents\/0103ee2d-bb14-4373-9c21-266f263f500f#fs-id1168329108070\" class=\"autogenerated-content\">(Figure)<\/a>, we can find the kinetic energy and hence the velocity needed for each point on the ellipse. We leave it as a challenge problem to find those transfer velocities for an Earth-to-Mars trip.<\/p>\n<p id=\"fs-id1168329183770\">We end this discussion by pointing out a few important details. First, we have not accounted for the gravitational potential energy due to Earth and Mars, or the mechanics of landing on Mars. In practice, that must be part of the calculations. Second, timing is everything. You do not want to arrive at the orbit of Mars to find out it isn\u2019t there. We must leave Earth at precisely the correct time such that Mars will be at the aphelion of our transfer ellipse just as we arrive. That opportunity comes about every 2 years. And returning requires correct timing as well. The total trip would take just under 3 years! There are other options that provide for a faster transit, including a gravity assist flyby of Venus. But these other options come with an additional cost in energy and danger to the astronauts.<\/p>\n<div id=\"fs-id1168329182768\" class=\"media-2\">\n<p id=\"fs-id1168329516298\">Visit this <a href=\"https:\/\/openstaxcollege.org\/l\/21plantripmars\">site<\/a> for more details about planning a trip to Mars.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168329125485\">\n<h3>Kepler\u2019s Second Law<\/h3>\n<p id=\"fs-id1168329145162\"><span>Kepler\u2019s second law<\/span> states that a planet sweeps out equal areas in equal times, that is, the area divided by time, called the areal velocity, is constant. Consider <a href=\"#CNX_UPhysics_13_05_Keplers2nd\" class=\"autogenerated-content\">(Figure)<\/a>. The time it takes a planet to move from position <em>A<\/em> to <em>B<\/em>, sweeping out area <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-1d92038a88902598d600782b06458e21_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#65;&#125;&#95;&#123;&#49;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"16\" width=\"19\" style=\"vertical-align: -4px;\" \/>, is exactly the time taken to move from position <em>C<\/em> to <em>D<\/em>, sweeping area <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-993eb4269832de62a6f735dff2e85a92_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#65;&#125;&#95;&#123;&#50;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"15\" width=\"20\" style=\"vertical-align: -3px;\" \/>, and to move from <em>E<\/em> to <em>F<\/em>, sweeping out area <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-c3102fb36cce8c77446b4689efb2d0de_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#65;&#125;&#95;&#123;&#51;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"15\" width=\"20\" style=\"vertical-align: -3px;\" \/>. These areas are the same: <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-eea1793c94371add7e9757acf734b826_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#65;&#125;&#95;&#123;&#49;&#125;&#61;&#123;&#65;&#125;&#95;&#123;&#50;&#125;&#61;&#123;&#65;&#125;&#95;&#123;&#51;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"16\" width=\"109\" style=\"vertical-align: -4px;\" \/>.<\/p>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_Keplers2nd\">\n<div class=\"bc-figcaption figcaption\">The shaded regions shown have equal areas and represent the same time interval.<\/div>\n<p><span id=\"fs-id1168329048142\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_Keplers2nd.jpg\" alt=\"An x y coordinate system is shown with the sun, also labeled as M, on the x axis to the left of the origin and an unlabeled point to the right of the origin. A planet, labeled also as m, is shown in the second quadrant. An arrow, labeled v, extends from the planet and points down and left, tangent to the orbit. Points A, B, C, D, E, and F are labeled on the orbit. Points A and B are in the third quadrant. The area of the region defined by A B and the sun is labeled A 1. Points C and D are in on the orbit on either side of the \u2013 y axis. The area of the region defined by C D and the sun is labeled A 2. Points E and F are in the first quadrant. The area of the region defined by E F and the sun is labeled A 3. The pair of points A B have the largest distance between them and is closest to the sun. E F have the smallest distance between them and are farthest from the sun.\" \/><\/span><\/p>\n<\/div>\n<p id=\"fs-id1168329063875\">Comparing the areas in the figure and the distance traveled along the ellipse in each case, we can see that in order for the areas to be equal, the planet must speed up as it gets closer to the Sun and slow down as it moves away. This behavior is completely consistent with our conservation equation, <a href=\"\/contents\/0103ee2d-bb14-4373-9c21-266f263f500f#fs-id1168326928404\" class=\"autogenerated-content\">(Figure)<\/a>. But we will show that Kepler\u2019s second law is actually a consequence of the conservation of angular momentum, which holds for any system with only radial forces.<\/p>\n<p id=\"fs-id1168329061906\">Recall the definition of angular momentum from <a href=\"\/contents\/3725769f-b3aa-424e-9d7b-a0ef8e6b0d19\" class=\"target-chapter\">Angular Momentum<\/a>, <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-354ab2bbc5a2485ef085a1406928e946_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#76;&#125;&#61;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"23\" width=\"71\" style=\"vertical-align: -2px;\" \/>. For the case of orbiting motion, <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-5a6d7ce7626d5b296413beb90c89f769_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#76;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"23\" width=\"13\" style=\"vertical-align: -2px;\" \/> is the angular momentum of the planet about the Sun, <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-23fc6b72ec91bb05929a36cf24c3b1df_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"13\" style=\"vertical-align: 1px;\" \/> is the position vector of the planet measured from the Sun, and <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-3d3005c25d2f8ef1414ce59d4eca32b8_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#61;&#109;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#118;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"23\" width=\"66\" style=\"vertical-align: -2px;\" \/> is the instantaneous linear momentum at any point in the orbit. Since the planet moves along the ellipse, <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-75fc482dd6ca1b9336d7baf560e8063a_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"23\" width=\"13\" style=\"vertical-align: -2px;\" \/> is always tangent to the ellipse.<\/p>\n<p id=\"fs-id1168329020269\">We can resolve the linear momentum into two components: a radial component <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-4cd1f5776f4d4fa4ecb89e63a234b8e5_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"25\" width=\"34\" style=\"vertical-align: -4px;\" \/> along the line to the Sun, and a component <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-158d686a5302b89c3426e53567affbad_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"27\" width=\"41\" style=\"vertical-align: -6px;\" \/> perpendicular to <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-23fc6b72ec91bb05929a36cf24c3b1df_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"13\" style=\"vertical-align: 1px;\" \/>. The cross product for angular momentum can then be written as<\/p>\n<p id=\"fs-id1168329395013\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-9c9ebd012f682041cf1f9d8bf284a102_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#76;&#125;&#61;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#61;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#108;&#101;&#102;&#116;&#40;&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;&#43;&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#61;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;&#43;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"33\" width=\"398\" style=\"vertical-align: -12px;\" \/>.<\/p>\n<p id=\"fs-id1168329169523\">The first term on the right is zero because <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-23fc6b72ec91bb05929a36cf24c3b1df_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"13\" style=\"vertical-align: 1px;\" \/> is parallel to <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-4cd1f5776f4d4fa4ecb89e63a234b8e5_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"25\" width=\"34\" style=\"vertical-align: -4px;\" \/>, and in the second term <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-23fc6b72ec91bb05929a36cf24c3b1df_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#114;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"13\" style=\"vertical-align: 1px;\" \/> is perpendicular to <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-158d686a5302b89c3426e53567affbad_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#112;&#125;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"27\" width=\"41\" style=\"vertical-align: -6px;\" \/>, so the magnitude of the cross product reduces to <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-b0b305d1890802f7800456c767c73f60_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#76;&#61;&#114;&#123;&#112;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;&#61;&#114;&#109;&#123;&#118;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"164\" style=\"vertical-align: -6px;\" \/>. Note that the angular momentum does <em>not<\/em> depend upon <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-3670b0c834d9dd4fb551af120fcd3303_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#112;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"30\" style=\"vertical-align: -4px;\" \/>. Since the gravitational force is only in the radial direction, it can change only <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-3670b0c834d9dd4fb551af120fcd3303_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#112;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#114;&#97;&#100;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"30\" style=\"vertical-align: -4px;\" \/> and not <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-48eda06fd2477ea50a1c501dfd30d533_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#112;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"14\" width=\"37\" style=\"vertical-align: -6px;\" \/>; hence, the angular momentum must remain constant.<\/p>\n<p id=\"fs-id1168329182115\">Now consider <a href=\"#CNX_UPhysics_13_05_area\" class=\"autogenerated-content\">(Figure)<\/a>. A small triangular area <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-f6f4f6e7863e8e38305ec5c1077cf9f3_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#65;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"13\" style=\"vertical-align: 0px;\" \/> is swept out in time <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-6e22acc0b91514a4aaf1954c300f3438_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"6\" style=\"vertical-align: 0px;\" \/>. The velocity is along the path and it makes an angle <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-761998727948942ceb1b5763e45f01e4_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"9\" style=\"vertical-align: 0px;\" \/> with the radial direction. Hence, the perpendicular velocity is given by <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-cd34b16bea90459c9a5b713d1b0af542_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#118;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;&#61;&#118;&#92;&#116;&#101;&#120;&#116;&#123;&#115;&#105;&#110;&#125;&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"100\" style=\"vertical-align: -6px;\" \/>. The planet moves a distance <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-359b9a7205402f670381728016c24fde_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#115;&#61;&#118;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#92;&#116;&#101;&#120;&#116;&#123;&#115;&#105;&#110;&#125;&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"78\" style=\"vertical-align: 0px;\" \/> projected along the direction perpendicular to <em>r<\/em>. Since the area of a triangle is one-half the base (<em>r<\/em>) times the height <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-61a7b57a5f7cba024aa5d1c90ed3ffaf_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#108;&#101;&#102;&#116;&#40;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#115;&#92;&#114;&#105;&#103;&#104;&#116;&#41;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"20\" style=\"vertical-align: -4px;\" \/>, for a small displacement, the area is given by <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-d2a0a561d894e1769fd45be21911e5f1_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#65;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;&#114;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#115;\" title=\"Rendered by QuickLaTeX.com\" height=\"22\" width=\"64\" style=\"vertical-align: -6px;\" \/>. Substituting for <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-d2ea351b54d5015287c3f403c692b563_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#115;\" title=\"Rendered by QuickLaTeX.com\" height=\"8\" width=\"8\" style=\"vertical-align: 0px;\" \/>, multiplying by <em>m<\/em> in the numerator and denominator, and rearranging, we obtain<\/p>\n<div id=\"fs-id1168056237254\" class=\"unnumbered\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-52bc489294e9d1f142e5dd08f5ab7b71_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#65;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;&#114;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#115;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;&#114;&#92;&#108;&#101;&#102;&#116;&#40;&#118;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#92;&#116;&#101;&#120;&#116;&#123;&#115;&#105;&#110;&#125;&#92;&#116;&#104;&#101;&#116;&#97;&#32;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#109;&#125;&#114;&#92;&#108;&#101;&#102;&#116;&#40;&#109;&#118;&#92;&#116;&#101;&#120;&#116;&#123;&#115;&#105;&#110;&#125;&#92;&#116;&#104;&#101;&#116;&#97;&#32;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#109;&#125;&#114;&#92;&#108;&#101;&#102;&#116;&#40;&#109;&#123;&#118;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#112;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#76;&#125;&#123;&#50;&#109;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#46;\" title=\"Rendered by QuickLaTeX.com\" height=\"22\" width=\"491\" style=\"vertical-align: -6px;\" \/><\/div>\n<div class=\"bc-figure figure\" id=\"CNX_UPhysics_13_05_area\">\n<div class=\"bc-figcaption figcaption\">The element of area <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-f6f4f6e7863e8e38305ec5c1077cf9f3_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#65;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"13\" style=\"vertical-align: 0px;\" \/> swept out in time <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-6e22acc0b91514a4aaf1954c300f3438_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"6\" style=\"vertical-align: 0px;\" \/> as the planet moves through angle <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-6e9b92c57cb6ff763cd860f2b4e918c0_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#92;&#118;&#97;&#114;&#112;&#104;&#105;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"11\" style=\"vertical-align: -4px;\" \/>. The angle between the radial direction and <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-08c90ae1637f7806fc89c3ad30294a55_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#115;&#116;&#97;&#99;&#107;&#114;&#101;&#108;&#123;&#92;&#116;&#111;&#32;&#125;&#123;&#118;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"13\" style=\"vertical-align: 1px;\" \/> is <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-761998727948942ceb1b5763e45f01e4_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#104;&#101;&#116;&#97;&#32;\" title=\"Rendered by QuickLaTeX.com\" height=\"12\" width=\"9\" style=\"vertical-align: 0px;\" \/>.<\/div>\n<p><span id=\"fs-id1168326918024\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_area.jpg\" alt=\"A diagram showing the sun and a planet separated by a distance r. The velocity vector of the planet is shown as an arrow pointing at an obtuse angle to the distance r between the sun and planet. The line connecting the sun and planet is extended past the planet as a dashed line, and another dashed line is drawn from the tip of the velocity arrow to the dashed extension of r. The dashed lines meet at a right angle and form a triangle with the velocity arrow forming the hypotenuse and the planet at one vertex. The angle near the planet is labeled theta. The hypotenuse is also labeled v delta t, and the side opposite the planet labeled v delta t sin theta. The triangular region defined by the sun, planet and the tip of the velocity arrow is labeled Delta A, and the angle near the sun is labeled delta phi.\" \/><\/span><\/p>\n<\/div>\n<p id=\"fs-id1168329292326\">The areal velocity is simply the rate of change of area with time, so we have<\/p>\n<div id=\"fs-id1168056552111\" class=\"unnumbered\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-5e78a58ff15ba1136de2dee05df1d8f2_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#92;&#116;&#101;&#120;&#116;&#123;&#97;&#114;&#101;&#97;&#108;&#32;&#118;&#101;&#108;&#111;&#99;&#105;&#116;&#121;&#125;&#61;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#102;&#114;&#97;&#99;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#65;&#125;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&Delta;&#125;&#116;&#125;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#76;&#125;&#123;&#50;&#109;&#125;&#46;\" title=\"Rendered by QuickLaTeX.com\" height=\"22\" width=\"195\" style=\"vertical-align: -6px;\" \/><\/div>\n<p id=\"fs-id1168326792738\">Since the angular momentum is constant, the areal velocity must also be constant. This is exactly Kepler\u2019s second law. As with Kepler\u2019s first law, Newton showed it was a natural consequence of his law of gravitation.<\/p>\n<div id=\"fs-id1168326861426\" class=\"media-2\">\n<p id=\"fs-id1168329266256\">You can view an <a href=\"https:\/\/openstaxcollege.org\/l\/21animationgrav\">animated version<\/a> of <a href=\"#CNX_UPhysics_13_05_Keplers2nd\" class=\"autogenerated-content\">(Figure)<\/a>, and many other interesting animations as well, at the School of Physics (University of New South Wales) site.<\/p>\n<\/div>\n<\/div>\n<div class=\"bc-section section\" id=\"fs-id1168326781140\">\n<h3>Kepler\u2019s Third Law<\/h3>\n<p id=\"fs-id1168329503239\"><span>Kepler\u2019s third law<\/span> states that the square of the period is proportional to the cube of the semi-major axis of the orbit. In <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25\" class=\"target-chapter\">Satellite Orbits and Energy<\/a>, we derived Kepler\u2019s third law for the special case of a circular orbit. <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> gives us the period of a circular orbit of radius <em>r<\/em> about Earth:<\/p>\n<div id=\"fs-id1168056224278\" class=\"unnumbered\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-283f1fd399c2ecd4f389d0b7f6472daf_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#84;&#61;&#50;&#92;&#112;&#105;&#32;&#92;&#115;&#113;&#114;&#116;&#123;&#92;&#102;&#114;&#97;&#99;&#123;&#123;&#114;&#125;&#94;&#123;&#51;&#125;&#125;&#123;&#71;&#123;&#77;&#125;&#95;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#69;&#125;&#125;&#125;&#125;&#46;\" title=\"Rendered by QuickLaTeX.com\" height=\"33\" width=\"114\" style=\"vertical-align: -12px;\" \/><\/div>\n<p id=\"fs-id1168327143853\">For an ellipse, recall that the semi-major axis is one-half the sum of the perihelion and the aphelion. For a circular orbit, the semi-major axis (<em>a<\/em>) is the same as the radius for the orbit. In fact, <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> gives us Kepler\u2019s third law if we simply replace <em>r<\/em> with <em>a<\/em> and square both sides.<\/p>\n<div id=\"fs-id1168326821418\" class=\"equation-callout\">\n<div id=\"fs-id1168329126738\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-b3162c95f35cbdf6b803f718baa5254d_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#61;&#92;&#102;&#114;&#97;&#99;&#123;&#52;&#123;&#92;&#112;&#105;&#32;&#125;&#94;&#123;&#50;&#125;&#125;&#123;&#71;&#77;&#125;&#123;&#97;&#125;&#94;&#123;&#51;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"24\" width=\"89\" style=\"vertical-align: -6px;\" \/><\/div>\n<\/div>\n<p id=\"fs-id1168329191321\">We have changed the mass of Earth to the more general <em>M<\/em>, since this equation applies to satellites orbiting any large mass.<\/p>\n<div id=\"fs-id1168326766432\" class=\"textbox examples\">\n<p id=\"fs-id1168329517500\"><span>Orbit of Halley\u2019s Comet<\/span><br \/>\nDetermine the semi-major axis of the orbit of <span class=\"no-emphasis\">Halley\u2019s comet<\/span>, given that it arrives at perihelion every 75.3 years. If the perihelion is 0.586 AU, what is the aphelion?<\/p>\n<p id=\"fs-id1168326787614\"><span>Strategy<\/span><br \/>\nWe are given the period, so we can rearrange <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a>, solving for the semi-major axis. Since we know the value for the perihelion, we can use the definition of the semi-major axis, given earlier in this section, to find the aphelion. We note that 1 Astronomical Unit (AU) is the average radius of Earth\u2019s orbit and is defined to be <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-fa6b04333bcdd40be3379d7ee28c89f3_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#49;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#65;&#85;&#125;&#61;&#49;&#46;&#53;&#48;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#49;&#49;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#109;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"16\" width=\"151\" style=\"vertical-align: -1px;\" \/>.<\/p>\n<p id=\"fs-id1168326764458\"><span>Solution<\/span><br \/>\nRearranging <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a> and inserting the values of the period of Halley\u2019s comet and the mass of the Sun, we have<\/p>\n<div id=\"fs-id1168056579806\" class=\"unnumbered\">\n<pre class=\"ql-errors\">*** QuickLaTeX cannot compile formula:\n&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#123;&#92;&#108;&#101;&#102;&#116;&#40;&#92;&#102;&#114;&#97;&#99;&#123;&#71;&#77;&#125;&#123;&#52;&#123;&#92;&#112;&#105;&#32;&#125;&#94;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;&#32;&#61;&#123;&#92;&#108;&#101;&#102;&#116;&#40;&#92;&#102;&#114;&#97;&#99;&#123;&#92;&#108;&#101;&#102;&#116;&#40;&#54;&#46;&#54;&#55;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#45;&#49;&#49;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#78;&#125;&middot;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#109;&#125;&#125;&#94;&#123;&#50;&#125;&#123;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#107;&#103;&#125;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#108;&#101;&#102;&#116;&#40;&#50;&#46;&#48;&#48;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#51;&#48;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#107;&#103;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#123;&#52;&#123;&#92;&#112;&#105;&#32;&#125;&#94;&#123;&#50;&#125;&#125;&#123;&#92;&#108;&#101;&#102;&#116;&#40;&#55;&#53;&#46;&#51;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#121;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#51;&#54;&#53;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#100;&#97;&#121;&#115;&#47;&#121;&#114;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#50;&#52;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#104;&#114;&#47;&#100;&#97;&#121;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#51;&#54;&#48;&#48;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#115;&#47;&#104;&#114;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#46;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#101;&#110;&#100;&#123;&#97;&#114;&#114;&#97;&#121;&#125;\n\n*** Error message:\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#35;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#32;&#105;&#110;&#32;&#97;&#108;&#105;&#103;&#110;&#109;&#101;&#110;&#116;&#32;&#112;&#114;&#101;&#97;&#109;&#98;&#108;&#101;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#97;&#108;&#105;&#103;&#110;&#109;&#101;&#110;&#116;&#32;&#116;&#97;&#98;&#32;&#104;&#97;&#115;&#32;&#98;&#101;&#101;&#110;&#32;&#99;&#104;&#97;&#110;&#103;&#101;&#100;&#32;&#116;&#111;&#32;&#92;&#99;&#114;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#36;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#123;&#92;&#108;&#101;&#102;&#116;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#92;&#108;&#101;&#102;&#116;&#40;&#92;&#102;&#114;&#97;&#99;&#123;&#71;&#77;&#125;&#123;&#52;&#123;&#92;&#112;&#105;&#32;&#125;&#94;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#125;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#125;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#125;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#50;&#125;&#125;&#123;&#84;&#125;&#94;&#123;&#50;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#125;&#94;&#123;&#49;&#92;&#116;&#101;&#120;&#116;&#123;&#47;&#125;&#51;&#125;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#38;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n\n<\/pre>\n<\/div>\n<p id=\"fs-id1168329173624\">This yields a value of <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-e60f8d5ab0b0287f37c87433fc9961cf_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#50;&#46;&#54;&#55;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#49;&#50;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#109;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"16\" width=\"89\" style=\"vertical-align: -1px;\" \/> or 17.8 AU for the semi-major axis.<\/p>\n<p id=\"fs-id1168329041363\">The semi-major axis is one-half the sum of the aphelion and perihelion, so we have<\/p>\n<div id=\"fs-id1168056151854\" class=\"unnumbered\">\n<pre class=\"ql-errors\">*** QuickLaTeX cannot compile formula:\n&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#38;&#32;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;&#92;&#108;&#101;&#102;&#116;&#40;&#92;&#116;&#101;&#120;&#116;&#123;&#97;&#112;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#43;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#116;&#101;&#120;&#116;&#123;&#97;&#112;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#38;&#32;&#61;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#38;&#32;&#50;&#97;&#45;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#46;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#101;&#110;&#100;&#123;&#97;&#114;&#114;&#97;&#121;&#125;\n\n*** Error message:\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#35;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#32;&#105;&#110;&#32;&#97;&#108;&#105;&#103;&#110;&#109;&#101;&#110;&#116;&#32;&#112;&#114;&#101;&#97;&#109;&#98;&#108;&#101;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#97;&#108;&#105;&#103;&#110;&#109;&#101;&#110;&#116;&#32;&#116;&#97;&#98;&#32;&#104;&#97;&#115;&#32;&#98;&#101;&#101;&#110;&#32;&#99;&#104;&#97;&#110;&#103;&#101;&#100;&#32;&#116;&#111;&#32;&#92;&#99;&#114;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#97;&#108;&#105;&#103;&#110;&#109;&#101;&#110;&#116;&#32;&#116;&#97;&#98;&#32;&#104;&#97;&#115;&#32;&#98;&#101;&#101;&#110;&#32;&#99;&#104;&#97;&#110;&#103;&#101;&#100;&#32;&#116;&#111;&#32;&#92;&#99;&#114;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#36;&#92;&#98;&#101;&#103;&#105;&#110;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#38;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#36;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#38;&#32;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#123;&#97;&#114;&#114;&#97;&#121;&#125;&#123;&#125;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#97;&#38;&#32;&#61;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#38;&#32;&#92;&#102;&#114;&#97;&#99;&#123;&#49;&#125;&#123;&#50;&#125;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#125;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#110;&#125;&#43;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#110;&#125;&#43;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;\r\n&#77;&#105;&#115;&#115;&#105;&#110;&#103;&#32;&#125;&#32;&#105;&#110;&#115;&#101;&#114;&#116;&#101;&#100;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#110;&#125;&#43;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;\r\n&#69;&#120;&#116;&#114;&#97;&#32;&#125;&#44;&#32;&#111;&#114;&#32;&#102;&#111;&#114;&#103;&#111;&#116;&#116;&#101;&#110;&#32;&#36;&#46;\r\n&#108;&#101;&#97;&#100;&#105;&#110;&#103;&#32;&#116;&#101;&#120;&#116;&#58;&#32;&#46;&#46;&#46;&#110;&#125;&#43;&#92;&#116;&#101;&#120;&#116;&#123;&#112;&#101;&#114;&#105;&#104;&#101;&#108;&#105;&#111;&#110;&#125;&#92;&#114;&#105;&#103;&#104;&#116;&#41;&#92;&#104;&#102;&#105;&#108;&#108;&#32;&#92;&#92;&#32;&#92;&#104;&#102;&#105;&#108;&#108;\r\n\n<\/pre>\n<\/div>\n<p id=\"fs-id1168327144713\">Substituting for the values, we found for the semi-major axis and the value given for the perihelion, we find the value of the aphelion to be 35.0 AU.<\/p>\n<p id=\"fs-id1168329518634\"><span>Significance<\/span><br \/>\nEdmond <span class=\"no-emphasis\">Halley<\/span>, a contemporary of Newton, first suspected that three comets, reported in 1531, 1607, and 1682, were actually the same comet. Before Tycho Brahe made measurements of comets, it was believed that they were one-time events, perhaps disturbances in the atmosphere, and that they were not affected by the Sun. Halley used Newton\u2019s new mechanics to predict his namesake comet\u2019s return in 1758.<\/p>\n<\/div>\n<div id=\"fs-id1168326788503\" class=\"check-understanding\">\n<div id=\"fs-id1168329171728\">\n<div id=\"fs-id1168326855597\">\n<p id=\"fs-id1168329511181\"><strong>Check Your Understanding<\/strong> The nearly circular orbit of Saturn has an average radius of about 9.5 AU and has a period of 30 years, whereas Uranus averages about 19 AU and has a period of 84 years. Is this consistent with our results for Halley\u2019s comet?<\/p>\n<\/div>\n<div id=\"fs-id1168326822487\">\n<p id=\"fs-id1168329148442\">The semi-major axis for the highly elliptical orbit of Halley\u2019s comet is 17.8 AU and is the average of the perihelion and aphelion. This lies between the 9.5 AU and 19 AU orbital radii for Saturn and Uranus, respectively. The radius for a circular orbit is the same as the semi-major axis, and since the period increases with an increase of the semi-major axis, the fact that Halley\u2019s period is between the periods of Saturn and Uranus is expected.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"textbox key-takeaways\" id=\"fs-id1168326765523\">\n<h3>Summary<\/h3>\n<ul id=\"fs-id1168327054984\">\n<li>All orbital motion follows the path of a conic section. Bound or closed orbits are either a circle or an ellipse; unbounded or open orbits are either a parabola or a hyperbola.<\/li>\n<li>The areal velocity of any orbit is constant, a reflection of the conservation of angular momentum.<\/li>\n<li>The square of the period of an elliptical orbit is proportional to the cube of the semi-major axis of that orbit.<\/li>\n<\/ul>\n<\/div>\n<div class=\"review-conceptual-questions\" id=\"fs-id1168329320256\">\n<h3>Conceptual Questions<\/h3>\n<div id=\"fs-id1168329160078\">\n<div id=\"fs-id1168329340846\">\n<p id=\"fs-id1168326763270\">Are Kepler\u2019s laws purely descriptive, or do they contain causal information?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329332078\">\n<div id=\"fs-id1168326777238\">\n<p id=\"fs-id1168329130138\">In the diagram below for a satellite in an elliptical orbit about a much larger mass, indicate where its speed is the greatest and where it is the least. What conservation law dictates this behavior? Indicate the directions of the force, acceleration, and velocity at these points. Draw vectors for these same three quantities at the two points where the <em>y<\/em>-axis intersects (along the semi-minor axis) and from this determine whether the speed is increasing decreasing, or at a max\/min.<\/p>\n<p><span id=\"fs-id1168326759021\"><img decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandbox\/wp-content\/uploads\/sites\/289\/2017\/11\/CNX_UPhysics_13_05_P65_img.jpg\" alt=\"A diagram showing an x y coordinate system and an ellipse, centered on the origin with foci on the x axis. The focus on the left is labeled f 1 and M. The focus on the right is labeled f 2. A location labeled as m is shown above f 2. The right triangle defined by f 1, f 2, and m is shown in red. The clockwise direction tangent to the ellipse is indicated by blue arrows.\" \/><\/span><\/p>\n<\/div>\n<div id=\"fs-id1168329187953\">\n<p id=\"fs-id1168329191139\">The speed is greatest where the satellite is closest to the large mass and least where farther away\u2014at the periapsis and apoapsis, respectively. It is conservation of angular momentum that governs this relationship. But it can also be gleaned from conservation of energy, the kinetic energy must be greatest where the gravitational potential energy is the least (most negative). The force, and hence acceleration, is always directed towards <em>M<\/em> in the diagram, and the velocity is always tangent to the path at all points. The acceleration vector has a tangential component along the direction of the velocity at the upper location on the <em>y<\/em>-axis; hence, the satellite is speeding up. Just the opposite is true at the lower position.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"review-problems\" id=\"fs-id1168326822588\">\n<h3>Problems<\/h3>\n<div id=\"fs-id1168329105797\">\n<div id=\"fs-id1168329022150\">\n<p id=\"fs-id1168329519026\">Calculate the mass of the Sun based on data for average Earth\u2019s orbit and compare the value obtained with the Sun\u2019s commonly listed value of <img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-c5db2df48faec0bdecc11a41f1758072_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#49;&#46;&#57;&#56;&#57;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#51;&#48;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#107;&#103;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"100\" style=\"vertical-align: -3px;\" \/>.<\/p>\n<\/div>\n<div>\n<p id=\"fs-id1168329450483\"><img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-047ec8c207e3c9f759c6fd420194dee7_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#49;&#46;&#57;&#56;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#51;&#48;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#107;&#103;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"18\" width=\"91\" style=\"vertical-align: -3px;\" \/>; The values are the same within 0.05%.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329194156\">\n<div id=\"fs-id1168329083138\">\n<p id=\"fs-id1168326842605\">Io orbits Jupiter with an average radius of 421,700 km and a period of 1.769 days. Based upon these data, what is the mass of Jupiter?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168326926286\">\n<div id=\"fs-id1168329443467\">\n<p id=\"fs-id1168329156360\">The \u201cmean\u201d orbital radius listed for astronomical objects orbiting the Sun is typically not an integrated average but is calculated such that it gives the correct period when applied to the equation for circular orbits. Given that, what is the mean orbital radius in terms of aphelion and perihelion?<\/p>\n<\/div>\n<div id=\"fs-id1168329510821\">\n<p id=\"fs-id1168329107484\">Compare <a href=\"\/contents\/b97a10e0-d98b-4b67-8210-0a23d7ba9e25#fs-id1168327874347\" class=\"autogenerated-content\">(Figure)<\/a> and <a href=\"#fs-id1168329126738\" class=\"autogenerated-content\">(Figure)<\/a> to see that they differ only in that the circular radius, <em>r<\/em>, is replaced by the semi-major axis, <em>a<\/em>. Therefore, the mean radius is one-half the sum of the aphelion and perihelion, the same as the semi-major axis.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329196621\">\n<div id=\"fs-id1168329184371\">\n<p id=\"fs-id1168329264997\">The perihelion of Halley\u2019s comet is 0.586 AU and the aphelion is 17.8 AU. Given that its speed at perihelion is 55 km\/s, what is the speed at aphelion (<img loading=\"lazy\" decoding=\"async\" src=\"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-content\/ql-cache\/quicklatex.com-9ec0bb4ea233075b8f3d7ab6af9d4273_l3.png\" class=\"ql-img-inline-formula quicklatex-auto-format\" alt=\"&#49;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#65;&#85;&#125;&#61;&#49;&#46;&#52;&#57;&#54;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&times;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#123;&#49;&#48;&#125;&#94;&#123;&#49;&#49;&#125;&#92;&#112;&#104;&#97;&#110;&#116;&#111;&#109;&#123;&#92;&#114;&#117;&#108;&#101;&#123;&#48;&#46;&#50;&#101;&#109;&#125;&#123;&#48;&#101;&#120;&#125;&#125;&#92;&#116;&#101;&#120;&#116;&#123;&#109;&#125;\" title=\"Rendered by QuickLaTeX.com\" height=\"16\" width=\"159\" style=\"vertical-align: -1px;\" \/>)? (<em>Hint:<\/em> You may use either conservation of energy or angular momentum, but the latter is much easier.)<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329319495\">\n<div id=\"fs-id1168326792076\">\n<p id=\"fs-id1168326857947\">The perihelion of the comet Lagerkvist is 2.61 AU and it has a period of 7.36 years. Show that the aphelion for this comet is 4.95 AU.<\/p>\n<\/div>\n<div id=\"fs-id1168329148430\">\n<p id=\"fs-id1168329169186\">The semi-major axis, 3.78 AU is found from the equation for the period. This is one-half the sum of the aphelion and perihelion, giving an aphelion distance of 4.95 AU.<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168326939686\">\n<div id=\"fs-id1168329071274\">\n<p id=\"fs-id1168329055659\">What is the ratio of the speed at perihelion to that at aphelion for the comet Lagerkvist in the previous problem?<\/p>\n<\/div>\n<\/div>\n<div id=\"fs-id1168329151836\">\n<div id=\"fs-id1168329047827\">\n<p id=\"fs-id1168329061232\">Eros has an elliptical orbit about the Sun, with a perihelion distance of 1.13 AU and aphelion distance of 1.78 AU. What is the period of its orbit?<\/p>\n<\/div>\n<div id=\"fs-id1168329181708\">\n<p id=\"fs-id1168329064510\">1.75 years<\/p>\n<\/div>\n<\/div>\n<\/div>\n<div class=\"textbox shaded\">\n<h3>Glossary<\/h3>\n<dl id=\"fs-id1168329331558\">\n<dt>aphelion<\/dt>\n<dd id=\"fs-id1168326837993\">farthest point from the Sun of an orbiting body; the corresponding term for the Moon\u2019s farthest point from Earth is the apogee<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329517229\">\n<dt>Kepler\u2019s first law<\/dt>\n<dd id=\"fs-id1168326765861\">law stating that every planet moves along an ellipse, with the Sun located at a focus of the ellipse<\/dd>\n<\/dl>\n<dl id=\"fs-id1168326790250\">\n<dt>Kepler\u2019s second law<\/dt>\n<dd id=\"fs-id1168329461373\">law stating that a planet sweeps out equal areas in equal times, meaning it has a constant areal velocity<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329137868\">\n<dt>Kepler\u2019s third law<\/dt>\n<dd id=\"fs-id1168329188942\">law stating that the square of the period is proportional to the cube of the semi-major axis of the orbit<\/dd>\n<\/dl>\n<dl id=\"fs-id1168329454958\">\n<dt>perihelion<\/dt>\n<dd id=\"fs-id1168326778106\">point of closest approach to the Sun of an orbiting body; the corresponding term for the Moon\u2019s closest approach to Earth is the perigee<\/dd>\n<\/dl>\n<\/div>\n","protected":false},"author":211,"menu_order":1,"template":"","meta":{"pb_show_title":"on","pb_short_title":"","pb_subtitle":"","pb_authors":[],"pb_section_license":"all-rights-reserved"},"chapter-type":[],"contributor":[],"license":[56],"class_list":["post-777","chapter","type-chapter","status-publish","hentry","license-all-rights-reserved"],"part":743,"_links":{"self":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapters\/777","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapters"}],"about":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/wp\/v2\/types\/chapter"}],"author":[{"embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/wp\/v2\/users\/211"}],"version-history":[{"count":1,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapters\/777\/revisions"}],"predecessor-version":[{"id":778,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapters\/777\/revisions\/778"}],"part":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/parts\/743"}],"metadata":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapters\/777\/metadata\/"}],"wp:attachment":[{"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/wp\/v2\/media?parent=777"}],"wp:term":[{"taxonomy":"chapter-type","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/pressbooks\/v2\/chapter-type?post=777"},{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/wp\/v2\/contributor?post=777"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/pressbooks.bccampus.ca\/universityphysicssandboxbook1\/wp-json\/wp\/v2\/license?post=777"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}