05. capacitors.pdf
TRANSCRIPT
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Engr. M Abdul Rehman
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The elements are capable to amplify the signal are called "Active Elements", i.e. resistors, capacitors, diodes, inductors, and switches.
The elements which will receive the energy and dissipate or store it are called "Passive Elements“ i.e. transistors, triacs, varistors, vacuum tubes, relays, and op-amps.
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Unlike the resistor, Capacitors display their total Characteristics only when a change in voltage or current is made in the circuit in which it exist.
In addition, if we consider the ideal situation, they do not Dissipate Energy as does the resistor but store it in a form that can be returned to the circuit whenever required by the circuit design.
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A force of attraction or repulsion exists between two charged bodies.
This electric field is represented by electric flux lines, which are drawn to indicate the strength of the electric field at any point around the charged body; that is, the denser the lines of flux, the stronger the electric field.
The flux per unit area (flux density) is represented by the capital letter D and is determined by
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Electric flux lines always extend from a positively charged body to a negatively charged body
The Electric Field Strength that a point is the force acting on a unit positive charge at that point
If Q2=1, then?
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Capacitance is a measure of a capacitor’s ability to store charge on its plates, in other words its storage capacity.
Two parallel plates of a conducting material separated by an air gap have been connected through a switch and a resistor to a battery.
If the parallel plates are initially uncharged and the switch is left open, no net positive or negative charge will exist on either plate.
The instant the switch is closed, however, electrons are drawn from the upper plate through the resistor to the positive terminal of the battery.
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Electrons are being repelled by the negative terminal through the lower conductor to the bottom plate at the same rate they are being drawn to the positive terminal.
This transfer of electrons continues until the potential difference across the parallel plates is exactly equal to the battery voltage.
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At the edges, the flux lines extend outside the common surface area of the plates, producing an effect known as fringing.
This effect reduces capacitance somewhat, can be neglected for most practical applications.
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The purpose of the dielectric is to create an electric field to oppose the electric field set up by free charges on the parallel plates.
If a potential difference of V volts is applied across the two plates separated by a distance of d, the electric field strength between the plates is determined by
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The ratio of the permittivity of any dielectric to that of a vacuum is called the relative permittivity
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Determine the capacitance of each capacitor
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For the following capacitora. Determine the capacitance.
b. Determine the electric field strength between the plates if 450 V are applied across the plates.
c. Find the resulting charge on each plate.
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A sheet of mica 1.5 mm thick having the same area as the plates is inserted between the plates of a Capacitora. Find the electric field strength between the plates.
b. Find the charge on each plate.
c. Find the capacitance.
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There are free electrons in every dielectric due in part to impurities in the dielectric and forces within the material itself.
When a voltage is applied across the plates of a capacitor, a leakage current due to the free electrons flows from one plate to the other.
The current is usually so small, however, that it can be neglected for most practical applications.
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Polarized, Fixed and Variable.
The symbol of polarized capacitor
The symbol for a fixed capacitor is
The symbol for a variable capacitor is
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Electrolytic Capacitor◦ It is a type of capacitor that uses an electrolyte as one of
its plates to achieve a larger capacitance per unit volume than other types.
◦ All capacitors conduct AC and block DC and can be used, amongst other applications, to couple circuit blocks allowing AC signals to be transferred while blocking DC power, to store energy, and to filter signals according to their frequency.
◦ Electrolytic capacitors are polarized; hence, they can only be operated with DC.
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Fixed Capacitors◦ Many types of fixed capacitors are available today. Some
of the most common are the mica, ceramic, electrolytic, tantalum, and polyester-film capacitors.
◦ The typical flat mica capacitor consists basically of mica sheets separated by sheets of metal foil.
◦ Data such as capacitance and working voltage are printed on the outer wrapping if the polyester capacitor is large enough.
◦ Color coding is used on smaller devices
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Variable Capacitors◦ Usually the dielectric for variable capacitors is air.
◦ Capacitance is changed by turning the shaft at one end to vary the common area of the movable and fixed plates.
◦ The greater the common area, the larger the capacitance
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Due to the small size of some capacitors, various marking schemes have been adopted to provide the capacitance level, the tolerance, and, if possible, the maximum working voltage.
In general the size of the capacitor is the first indicator of its value. ◦ The smaller units are typically in pico-farads (pF) and the
larger units in microfarads (mF).
◦ On larger mF units, the value can usually be printed on the jacket with the tolerance and maxi-mum working voltage.
◦ However, smaller units need to use some form of abbreviation
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Measurement is done using a digital reading capacitance meter.
Simply place the capacitor between the provided clips with the proper polarity, and the meter will display the level of capacitance.
The longer leg is positive and shorter leg is negative in Electrolytic Capacitors.
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The instant the switch is closed, electrons are drawn from the top plate and deposited on the bottom plate by the battery, resulting in a net positive charge on the top plate and a negative charge on the bottom plate. The transfer of electrons is very rapid at first, slowing down as
the potential across the capacitor approaches the applied voltage of the battery.
When the voltage across the capacitor equals the battery voltage, the transfer of electrons will cease and the plates will have a net charge determined by
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When the switch is closed at t =0, the current jumps to a value limited only by the resistance of the network and then decays to zero as the plates are charged.
The rapid decay in current level, revealing that the amount of charge deposited on the plates per unit time is rapidly decaying also.
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Since the voltage across the plates is directly related to the charge on the plates by Vc, , the rapid rate with which charge is initially deposited on the plates will result in a rapid increase in Vc.
Eventually, the flow of charge will stop, the current I will be zero, and the voltage will cease to change in magnitude the charging phase has passed.
At this point the capacitor takes on the characteristics o.f an open circuit
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A capacitor can be replaced by an open-circuit equivalent once the charging phase has passed.
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Charging Current ic
◦ Factor RC is called the time constant of the system.
◦ Its symbol is the Greek letter t (tau), and its unit of measure is the second.
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The current iC of a capacitive network is essentially zero after five time constants of the charging phase have passed in a dc network.
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Charging Voltage Vc
◦ The factor is a decaying function, the factor
will grow toward a maximum value of 1 with time.
◦ As E is the multiplying factor, the voltage Vc is E volts after five time constants of the charging phase.
◦ If we keep R constant and reduce C, the product RC will decrease, and the rise time of five time constants will decrease and vice versa.
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Voltage across Resistor VR
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a) Find the mathematical expressions and plots the curves for the transient behavior of Vc, ic, VR
when the switch is moved to position 1.
b) How much time must pass before it can be assumed, for all practical purposes, that Vc =E, ic=E volts?
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Solutions
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Will start when the switch is moved to position 2. Capacitor will begin to dischargeat a rate sensitive to the same time constant. The established voltage across the capacitor will create a flow ofcharge in the closed path that will eventually discharge the
capacitor completely. The capacitor functions like a battery with a decreasing
terminal voltage.
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Discharging Current◦ The current iC has reversed direction, changing the polarity of
the voltage across R.
◦ During the discharge phase the current will also decrease with time.
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Discharging Voltage Vc
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Voltage across Resistor VR
◦ The voltage drop across resistor R will be same as that of capacitor.
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After Vc has reached its final value of 40 V, the switch is thrown into position 2
Find the mathematical expressions for the transient behavior of VC, iC, and VR after the closing of the switch. Plot the curves for VC, iC, and VR using the defined directions and polarities. Assume that t=0 when the switch is moved to position 2
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a. Find the mathematical expression for the transient behavior of the
voltage across the capacitor if the switch is thrown into position 1 at t = 0 s.
b. Repeat part (a) for iC. c. Find the mathematical expressions for the response of vC and
iC if the switch is thrown into position 2 at 30 ms (assuming that the leakage resistance of the capacitor is infinite ohms).
d. Find the mathematical expressions for the voltage vC and current iC if the switch is thrown into position 3 at t=48 ms.
e. Plot the waveforms obtained in parts (a) through (d) on the same time axis for the voltage vC and the current iC using the defined polarity and current direction.
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a. Find the mathematical expression for the transient behavior of the voltage across the capacitor if the switch is thrown into position 1 at t=0 s.
b. Repeat part (a) for iC.
c. Find the mathematical expression for the response of vC and iC if the switch is thrown into position 2 at t =1RC of the charging phase.
d. Plot the waveforms obtained in parts (a) through (c) on the same time axis for the voltage vC and the current iC using the defined polarity and current direction
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We will now examine the effect of a charge, and therefore a voltage on the plates at the instant the switching action takes place.
The voltage across the capacitor at this instant is called the initial value.
Once the switch is thrown, the transient phase will commence until a leveling off occurs after five time constants.
This region of relatively fixed value that follows the transient response is called the steady-state region, and the resulting value is called the steady-state or final value.
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Using the transient equation developed in the previous section, an equation for the voltage vCcan be written for the entire time interval
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The capacitor in the following figure has an initial voltage of 4V.◦ a. Find the mathematical expression for the voltage
across the capacitor once the switch is closed.
◦ b. Find the mathematical expression for the current during the transient period.
◦ c. Sketch the waveform for each from initial value to final value.
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On occasion it will be necessary to determine the voltage or current at a particular instant of time that is not an integral multiple of t. For example, if
the voltage vC may be required at t=5 ms, which does
not correspond to a particular value of t.
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Occasions will arise in which the network does not have the simple series form.
It will then be necessary first to find the Théveninequivalent circuit for the network external to the capacitive element. Eth will then be the source voltage E, and Rth will be the resistance R. The time constant is then t=RthC.
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a. Find the mathematical expression for the transient behavior of the voltage vC and the current iC following the closing of the switch (position 1 at t=0 s).
b. Find the mathematical expression for the voltage vCand current iC as a function of time if the switch is thrown into position 2 at t=9 ms.
c. Draw the resultant waveforms of parts (a) and (b) on the same time axis.
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The capacitor of is initially charged to 40 V. Find the mathematical expression for vC after the closing of the switch.
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For the network find the mathematical expression for the voltage vC after the closing of the switch (at t=0).
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Capacitors, like resistors, can be placed in series and in parallel.
Increasing levels of capacitance can be obtained by placing capacitors in parallel, while decreasing levels can be obtained by placing capacitors in series.
For capacitors in series, the charge is the same on each capacitor
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Applying Kirchhoff’s voltage law around the closed loop gives
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a. Find the total capacitance.
b. Determine the charge on each plate.
c. Find the voltage across each capacitor.
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72Abdul Rehman (Circuit Analysis)
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73Abdul Rehman (Circuit Analysis)
a. Find the total capacitance.
b. Determine the charge on each plate.
c. Find the total charge.
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75Abdul Rehman (Circuit Analysis)
Find the voltage across and charge on each capaci-tor for the network.
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77Abdul Rehman (Circuit Analysis)
Find the voltage across and charge on capacitor C1 after it has charged up to its final value.
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Abdul Rehman (Circuit Analysis) 78
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79Abdul Rehman (Circuit Analysis)
Find the voltage across and charge on each capacitor of the network after each has charged up to its final value.
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Abdul Rehman (Circuit Analysis) 80
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81Abdul Rehman (Circuit Analysis)
The ideal capacitor does not dissipate any of the energy supplied to it.
It stores the energy in the form of an electric field between the con-ducting surfaces.
The power curve can be obtained by finding the product of the voltage and current at selected instants of time and connecting the points obtained.
The energy stored is represented by the shaded area under the power curve.
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Abdul Rehman (Circuit Analysis) 82
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83Abdul Rehman (Circuit Analysis)
Determine the energy stored by each capacitor.
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