{"id":4556,"date":"2021-06-27T17:02:55","date_gmt":"2021-06-28T00:02:55","guid":{"rendered":"https:\/\/gurumuda.net\/physics\/?p=4556"},"modified":"2021-06-27T17:02:55","modified_gmt":"2021-06-28T00:02:55","slug":"equation-of-capacitor-circuit","status":"publish","type":"post","link":"https:\/\/gurumuda.net\/physics\/equation-of-capacitor-circuit.htm","title":{"rendered":"Equation of capacitor circuit","gt_translate_keys":[{"key":"rendered","format":"text"}]},"content":{"rendered":"<h3 align=\"justify\">Article about The Equation of capacitor circuit<\/h3>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">A capacitor has a certain capacitance. If the required capacitance is not available, can be connected to two or more two capacitors to obtain the required capacitance. In order to properly connected the capacitor, it needs correct knowledge about the capacitor circuit. \ud83d\ude42<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><img loading=\"lazy\" decoding=\"async\" class=\"alignleft size-full wp-image-4557\" src=\"https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/2018\/10\/Equation-of-capacitor-circuit-1.png\" alt=\"Equation of capacitor circuit 1\" width=\"52\" height=\"78\" \/>Before studying the <a href=\"https:\/\/gurumuda.net\/physics\/definition-of-capacitor.htm\">capacitor<\/a> circuit, first, understand the following symbols. Two vertical lines on the capacitor symbol represent two conductors on parallel plate capacitors. In the battery symbol, a longer vertical line represents a high potential (+) and a shorter vertical line represents a low potential (-). The horizontal line of both the capacitor symbol and the battery symbol represents the cable.<\/span><\/span><!--more--><\/p>\n<h3 class=\"western\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><span lang=\"en-US\"><b>Series circuit<\/b><\/span><\/span><\/span><\/h3>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><img loading=\"lazy\" decoding=\"async\" class=\"alignleft size-medium wp-image-4558\" src=\"https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/2018\/10\/Equation-of-capacitor-circuit-2-300x165.png\" alt=\"Equation of capacitor circuit 2\" width=\"300\" height=\"165\" srcset=\"https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/sites\/28\/2018\/10\/Equation-of-capacitor-circuit-2-300x165.png 300w, https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/sites\/28\/2018\/10\/Equation-of-capacitor-circuit-2.png 307w\" sizes=\"auto, (max-width: 300px) 100vw, 300px\" \/>Two capacitors connected as in the left figure are called capacitors that are connected in series. The right figure is an equivalent capacitor that has a capacitance equivalent to the two series capacitors.<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">At first, the two capacitors were not electrically charged. After being connected to the battery, the plate of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> which is connected to the positive pole of the battery becomes positively charged. Because the electrons move out of it and the bottom plate of capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> which is connected to the negative pole of the battery becomes negatively charged because it receives electrons. Negatively charged electrons move because they are pulled by the positive pole of the battery, which is positively charged. <\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Then these electrons are rejected by the negatively charged of the negative pole of the battery, towards the bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">. The plate of the positively charged capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> pulls the electron from the top of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> so that the electrons move towards the bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">. As a result, the plate of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> becomes negatively charged and the plate of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> becomes positively charged.<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">The negative charge that exit from the top of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is as much as the negative charge that enters the bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2. A<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">nd the plate on the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> gets a positive charge that is equal to the negative charge exit from it. Likewise, the negative charge on the bottom plate of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">is equal to the positive charge on the plate of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">. So each conductor plate has the same amount of charge but the sign is different, where the top of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is charged + Q. <\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">The bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is charged -Q, the top of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is charged +Q, and the bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is charged -Q. In a series circuit, the amount of electric charge on the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> (Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">) = the amount of electric charge on capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> (Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">) = Q.<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">What about the electric potential? In a series circuit, the electric potential of the equivalent capacitor is equal to the electric potential of each capacitor, V = V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">+ V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">. The electric potential of capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= Q\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">, the electric potential of capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= Q\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2,<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> and the electric potential of the capacitor is V = Q\/C.<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">V = V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Q\/C = Q\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + Q\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Q\/C = Q (1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">)<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">1\/C = 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">If there are three capacitors that connected in series, the formula above changes to:<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">1\/C = 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">3<\/span><\/sub><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">If there are four capacitors, 1\/C<sub>4<\/sub> is added. Likewise, if there are five capacitors and so on. This is the formula for determining the capacitance of the equivalent capacitor for capacitors connected in series.<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Suppose C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">is 2 and C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">is 1 then the capacitance of the replacement capacitor is:<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">1\/C = 1\/C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + 1\/C<\/span><\/span><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><sub>2<\/sub> <\/span><\/span><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= 1\/2 + 1\/1 = 1\/2 + 2\/2 = 3\/2<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C\/1 = C = 2\/3<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Based on this calculation, it is concluded that the capacitance of the replacement capacitor is smaller than the capacitance of each capacitor connected in series.<\/span><\/span><\/p>\n<h3 class=\"western\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><span lang=\"en-US\"><b>Parallel circuit<\/b><\/span><\/span><\/span><\/h3>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><img loading=\"lazy\" decoding=\"async\" class=\"alignleft size-medium wp-image-4559\" src=\"https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/2018\/10\/Equation-of-capacitor-circuit-3-300x143.png\" alt=\"Equation of capacitor circuit 3\" width=\"300\" height=\"143\" srcset=\"https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/sites\/28\/2018\/10\/Equation-of-capacitor-circuit-3-300x143.png 300w, https:\/\/gurumuda.net\/physics\/wp-content\/uploads\/sites\/28\/2018\/10\/Equation-of-capacitor-circuit-3.png 343w\" sizes=\"auto, (max-width: 300px) 100vw, 300px\" \/>Two capacitors connected as in the left figure are called capacitors that are connected in parallel. The right figure is the replacement capacitor that has a capacitance equal to the two capacitors connected in parallel.<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">The plates of capacitors C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">1<\/span><\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> and C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">2<\/span><\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> are connected to the positive pole of the battery so that these two plates have high electric potential. Whereas the bottom plates of capacitors C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">and C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> are connected to the negative pole of the battery so that these two plates also have low electric potential. So it can be concluded that each capacitor that connected in parallel has a potential difference equal to the battery potential difference (V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= V<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> = V).<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">When the two capacitors that, connected in parallel, are connected to the battery, the positive pole of the battery pulls the electrons to the top plate. While the negative pole of the battery rejects the electrons into the lower plate so that the electron moves from the top to the bottom. The two plates lose electrons so that they become positively charged, and the two lower plates accept electrons so that they become negatively charged. The movement of electrons stops after the two conductor plates have a potential difference equal to the battery potential difference.<\/span><\/span><\/p>\n<p class=\"western\" align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">The top of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">and the bottom of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">store the same electric charge, but have an opposite sign. Likewise, the top piece of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">and the bottom piece of the capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> store the same electric charge but have opposite signs. If the electric charge stored in capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> and the electric charge stored in capacitor C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">is Q2,<\/span><\/span><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> then the amount of the electric charge stored in both capacitors that connected in parallel is Q = Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">. So the total electric charge on the capacitor connected in parallel is equal to the amount of charge on each capacitor.<\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">The electric charge in each capacitor connected in parallel is calculated by the equation Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> \u0394V and Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> = C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> \u0394V while the large electric charge on the replacement capacitor is calculated by the equation Q = C \u0394V. <\/span><\/span><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Where Q is the electric charge, C is capacitance and \u0394V is an electric potential difference. The equation Q = Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is reformulated by substitute Q:<\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Q = Q<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + Q<\/span><\/span><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><sub>2<\/sub> <\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C \u0394V = C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> \u0394V + C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> \u0394V <\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C \u0394V = \u0394V (C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">) <\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C = C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2<\/span><\/sub><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"><i>The potential difference of \u0394V is equal, so eliminated from the equation.<\/i><\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">If there are three capacitors connected in parallel, the formula above changes to:<\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C = C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">+ C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">3<\/span><\/sub><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">If there are four capacitors, C4 is added. Likewise, if there are five capacitors and so on. This is the formula for determining the capacitance of a replacement capacitor for capacitors connected in parallel.<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">If C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1<\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> is 2 and C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">is 1 then the capacitance of the replacement capacitor is:<\/span><\/span><\/p>\n<p><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">C = C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">1 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\"> + C<\/span><\/span><sub><span style=\"font-family: Times new roman, serif\">2 <\/span><\/sub><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">= 2 + 1 = 3<\/span><\/span><\/p>\n<p align=\"justify\"><span style=\"font-family: Times new roman, serif\"><span style=\"font-size: medium\">Based on this calculation, it is concluded that the capacitance of the replacement capacitor is greater than the capacitance of each capacitor connected in parallel.<\/span><\/span><\/p>\n<p align=\"justify\">\n","protected":false,"gt_translate_keys":[{"key":"rendered","format":"html"}]},"excerpt":{"rendered":"<p>Article about The Equation of capacitor circuit A capacitor has a certain capacitance. If the required capacitance is not available, can be connected to two or more two capacitors to obtain the required capacitance. In order to properly connected the capacitor, it needs correct knowledge about the capacitor circuit. \ud83d\ude42 Before studying the capacitor circuit, &#8230; <a title=\"Equation of capacitor circuit\" class=\"read-more\" href=\"https:\/\/gurumuda.net\/physics\/equation-of-capacitor-circuit.htm\" aria-label=\"Read more about Equation of capacitor circuit\">Read more<\/a><\/p>\n","protected":false,"gt_translate_keys":[{"key":"rendered","format":"html"}]},"author":1,"featured_media":0,"comment_status":"open","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"_seopress_titles_title":"","_seopress_titles_desc":"Article about The Equation of capacitor circuit A capacitor has a certain capacitance.","_seopress_robots_index":"","_seopress_robots_follow":"","_seopress_robots_imageindex":"","_seopress_robots_snippet":"","_seopress_robots_primary_cat":"","_seopress_robots_breadcrumbs":"","_seopress_robots_freeze_modified_date":"","_seopress_robots_custom_modified_date":"","_seopress_robots_canonical":"","_seopress_social_fb_title":"","_seopress_social_fb_desc":"","_seopress_social_fb_img":"","_seopress_social_fb_img_attachment_id":0,"_seopress_social_fb_img_width":0,"_seopress_social_fb_img_height":0,"_seopress_social_twitter_title":"","_seopress_social_twitter_desc":"","_seopress_social_twitter_img":"","_seopress_social_twitter_img_attachment_id":0,"_seopress_social_twitter_img_width":0,"_seopress_social_twitter_img_height":0,"_seopress_redirections_value":"","_seopress_redirections_enabled":"","_seopress_redirections_enabled_regex":"","_seopress_redirections_logged_status":"","_seopress_redirections_param":"","_seopress_redirections_type":0,"_seopress_analysis_target_kw":"Equation of capacitor circuit","_seopress_news_disabled":"","_seopress_video_disabled":"","_seopress_video":[],"_seopress_pro_schemas_manual":[],"_seopress_pro_rich_snippets_disable_all":"","_seopress_pro_rich_snippets_disable":[],"_seopress_pro_schemas":[],"footnotes":""},"categories":[2],"tags":[],"class_list":["post-4556","post","type-post","status-publish","format-standard","hentry","category-basic-physics-tutorials"],"gt_translate_keys":[{"key":"link","format":"url"}],"_links":{"self":[{"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/posts\/4556","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/comments?post=4556"}],"version-history":[{"count":0,"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/posts\/4556\/revisions"}],"wp:attachment":[{"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/media?parent=4556"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/categories?post=4556"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/gurumuda.net\/physics\/wp-json\/wp\/v2\/tags?post=4556"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}