Figure 1: (a) Diode cross section. (b) Reverse biased diode. (c) Forward biased diode.

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The Junction Diode Basic Operation The diode is fabricated of a semiconductor material, usually silicon, which is doped with two impurities. One side is doped with a donor or n-type impurity which releases electrons into the semiconductor lattice. These electrons are not bound and are free to move about. Because there is no net charge in the donor impurity, the n-type semiconductor is electrically neutral. The other side is doped with an acceptor or p-type impurity which imparts free holes into the lattice. A hole is the absence of an electron which acts as a positive charge. The p-type semiconductor is also electrically neutral because the acceptor material adds no net charge. Figure 1(a) illustrates the cross section of the diode. The junction is the dividing line between the n-type and p-type sides. Thermal energy causes the electrons and holes to move randomly. Electrons diffuse across thejunctionintothep-typesideandholesdiffuse across the junction into the n-type side. This causes a net positive charge to develop in the n-type side and a net negative charge to develop in the p-type side. These charges set up an electric field across the junction which is directed from the n-type side to the p-type side. The electric field opposes further diffusion of the electrons and holes. The region in which the electric field exists is called the depletion region. There are no free electrons or holes in this region because the electric field sweeps them out. Figure 1: (a) Diode cross section. (b) Reverse biased diode. (c) Forward biased diode. Figure 1(b) shows the diode with a battery connected across it. The polarity of the battery is such that it reinforces the electric field across the junction causing the depletion region to widen. The positive terminal pulls electrons in the n-type side away from the junction. The negative terminal pulls holes in the p-type side away from the junction. No current can flow. The diode is said to be reverse biased. Figure 1(c) shows the diode with the battery polarity reversed. The battery now tends to cancel out the electric field in the depletion region, causing its width to decrease. The positive terminal forces holes toward the junction. The negative terminal forces electrons toward the junction. A current flows which increases rapidly if the applied voltage is increased. The diode is said to be forward biased. i v Characteristics Figure 2(a) shows the circuit symbol for the diode. The arrow part of the symbol points in the direction of current flow when the diode is forward biased. The upper terminal is called the anode. The lower terminal is called the cathode. These names come from vacuum tube diodes. The theoretical equation for the diode current is µ vd i D I S exp 1 where I S is the saturation current, n is the emission coefficient, and V T is the thermal voltage. The emission coefficient accounts for recombinations of electrons and holes in the depletion region, which tend to decrease the current. For discrete diodes, it has the value n ' 2. For integrated circuit diodes, it has the value n ' 1. The reason it is different for the two cases is because an integrated circuit diode is fabricated as a bipolar transistor with the collector connected to the base. The impurity doping in transistors is done so as to minimize recombinations. Thus, n ' 1 when recombinations can be neglected. A typical plot of i D versus v D isgiveninfig. 2(b). Forv D 0.6V, the current is very small. For v D > 0.6V, the current increases rapidly with v D. The voltage at which the diode appears to begin conducting is called the cutin voltage. This is approximately 0.6V for the plot in Fig. 2(b). 1

Figure 2: (a) Diode symbol. (b) Typical current versus voltage. The thermal voltage is given by V T kt q where k is Boltzmann s constant, T is the Kelvin temperature, and q istheelectroniccharge.att 290 K, the thermal voltage has the value V T 0.025 V. The default value for T in SPICE is T 300 K. In this case, the thermal voltage has the value V T 0.02585 V. This value should be used in any hand calculations that are to be compared to SPICE simulations. Because V T increases with T, the equation for i D seems to imply that increasing T decreases i D. However, I S increases rapidly with temperature which causes i D to increase with T. A rule of thumb that is often quoted for silicon diodes is that if i D is held constant, v D decreases by about 2mV for each degree C as T increases. Example 1 Calculate the amount by which v D Assume exp (v D / ) À 1 and V T 0.025 V. wouldhavetobeincreasedtodoublethediodecurrent. Solution. We have Solution for v v D2 v D1 yields 2 I µ S [exp (v D2 / ) 1] I S [exp (v D1 / ) 1] ' exp vd2 v D1 v ln 2 17.3mV for n 1 34.7mV for n 2 This example illustrates how fast the diode current increases with increasing diode voltage. Reverse Breakdown If the diode is reverse biased and the voltage is increased, a point will be reached when the diode enters reverse breakdown and a current will flow. The voltage at which this occurs is called the zener voltage. Fig. 3 illustrates the variation of diode current with voltage. The reverse breakdown voltage is labeled V Z and the cutin voltage is labeled V γ. In diode applications, the reverse breakdown voltage must be greater than the maximum applied reverse voltage to prevent diode failure. As an example, diodes used to rectify 120 V rms ac line voltage must have a reverse breakdown voltage greater than 120 2170V. Diodes which are fabricated to have a specific valueofv Z are called zener diodes. These diodes are used as voltage reference diodes. The zener or reverse breakdown voltage is a function of the n and p type doping levels in the diode. The higher the doping, the lower the value of V Z.ForV Z less than approximately 4V, the breakdown is due to zener breakdown. For V Z greater than approximately 5V, the breakdown is due to avalanche breakdown. 2

Figure 3: Diode characteristics showing the zener voltage V Z andthecutinvoltagev γ. An example application of a zener diode is shown in Fig. 4. The circuit shows a dc source having a voltage V 1 connected to a zener diode and a load through a resistor R 1. If V 1 changes, V L remains approximately constant. Thus the diode acts as a constant voltage reference. The diode current is I Z V 1 V Z R 1 The power dissipated in the diode is given by V Z I Z. The power dissipated in the resistor R 1 is (V 1 V Z )(I Z + I L ). The power dissipated in the diode decreases as I L increases and the power dissipated in R 1 increases as I L increases. The power ratings of the diode and R 1 must be high enough to prevent thermal failure under worst case conditions for each. This means that the power rating of the diode must be chosen for the minimum anticipated value of I L and the power rating of R 1 must be chosen for the maximum anticipated value of I L. I L Figure 4: Example zener diode regulator. Example 2 For V 1 24V, V Z 12V,and2mA I L 10 ma, calculate the value of R 1 such that I Z 2mA and determine the minimum power ratings of R 1 and the zener diode in Fig. 4. Solution. The value of R 1 is calculated for the maximum value of I L. Thus the maximum current through R 1 is 2mA+10mA12mA.ThusR 1 (24V 12 V) /12 ma 1 kω. The minimum power rating for R 1 is 12 V 12 ma 144 mw. The minimum power rating for the zener diode is 12 V (12 ma 2 ma) 100 mw. Linear Model The linear model of the diode approximates the i v characteristics by a straight line that is tangent to the actual curve at the dc bias point. Fig. 5(a) shows the curve with the tangent line at the point (V D,I D ).The curve intersects the horizontal axis at the voltage V DO. For small changes in v D and i D about the tangent point, the tangent line gives a good approximation to the actual curve. The slope of the tangent line is given by m di D dv D (VD,I D) 1 µ VD I S exp I D + I S where the units of r d are ohms. The equation of the tangent line is i D V D V DO r d 3 1 r d

Figure 5: (a) i v characteristics with tangent line at (V D,I D ). (b) Linear diode model. The equivalent circuit which models this equation is shown in Fig. 5(b). Because v D V D when i D I D, it follows that the voltage V DO is given by V DO V D I D r d Example 3 A diode is biased at I D 1mA. It is given that I S 3.6 10 9 A, n 2,andV T 25.9mV. Solve for r d and V DO in the linear model. Solution. V D ln (I D /I S )0.649 V, r d /I D 51.8 Ω, V DO V D I D r d 0.598 V. Small-Signal Model Because the diode equation for i D as a function of v D is non-linear, the tools of linear circuit analysis cannot be applied, in general, to circuits containing diodes. However, if the diode current is known for a particular voltage,linearcircuitanalysiscanbeusedtopredictthechangeincurrentforagivenchangeinvoltage, provided the change is not very large. Such an approach is called a small-signal analysis. Let the diode voltage and current be written v D V D + v d i D I D + i d where V D and I D are dc bias values and v d and i d are small-signal changes about the bias values. Let the diode equation be denoted by i D f (v D ). We can write I D + i d f (V D + v d ) ' f (V D )+f 0 (V D ) v d where the approximation is a first-order Taylor series expansion about the point (V D,I D ). Because I D f (V D ), we can solve for i d to obtain i d f 0 (V D ) v d d µ ¾ VD ½I S exp 1 v d I µ S VD exp v d I D + I S v d dv D V T The small-signal resistance is defined as the ratio of v d to i d and is given by r d I D + I S ' I D This is the same r d as in the linear model of the diode in Fig. 5(b). This equation says that the diode small-signal resistance is inversely proportional to the current through it. Each time the current is doubled, the resistance is halved. It follows from the linear diode model that r d can be interpreted graphically as the reciprocal of the slope of the i D versus v D curve at the point (V D,I D ). 4

Figure 6: (a) Diode attenuator circuit. (b) Small-signal circuit for calculating v o. Figure 7: Plot of voltage gain versus control current. Example 4 Figure 6(a) shows a diode attenuator circuit. The input voltage v i is a small-signal differential voltage represented by two series sources with the common terminal grounded. The current I Q is a dc control current. Solve for the small-signal gain v o /v i. Assume the diodes are identical, n 2,andV T 0.025 V. Solution. For the dc solution, we set v i 0. In this case, v o 0. For identical diodes, the current I Q splits equally between the two. It follows the dc voltages across the diodes cancel in calculating V O so that V O 0. The small-signal resistance of each diode is r d1 r d2 2 /I Q 0.1/I Q. The small-signal circuit isshowninfig. 6(b). ThecurrentI Q does not appear in this circuit because it is a dc source which becomes an open circuit when zeroed. It follows by voltage division that v o v i r d1 + r d2 2R + r d1 + r d2 2 0.1/I Q 2R +2 0.1/I Q 1 1+10I Q R Thus the small-signal gain of the circuit can be varied by varying the dc current I Q. A typical plot of the gainversuscurrentisshowninfig.7. 5

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