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Electronic Devices & Circuits

Electronic Devices & Circuits. Khurram Bughio Lecturer Electrical Engineering, MUCET. Diode Model. Diode. A diode is a single pn junction device with conductive contacts and wire leads connected to each region, as shown in Figure.

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Electronic Devices & Circuits

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  1. Electronic Devices & Circuits Khurram Bughio Lecturer Electrical Engineering, MUCET

  2. Diode Model

  3. Diode • A diode is a single pn junction device with conductive contacts and wire leads connected to each region, as shown in Figure. • One part of the diode is an n-type semiconductor and the other part is a p-type semiconductor. • The n region is called the cathode and the p region is called the anode. • The "arrow" in the symbol points in the direction of conventional current (opposite to electron flow).

  4. Ideal Diode • The ideal diode is a simple switch. • When the diode is forward-biased, it acts like a closed (on) switch. • When the diode is reverse-biased. it acts like an open (off) switch. • The barrier potential, the forward dynamic resistance, and the reverse current are all neglected.

  5. In Figure, the ideal V-I characteristic curve graphically depicts the ideal diode operation. • Since the barrier potential and the forward dynamic resistance are neglected, the diode is assumed to have a zero voltage across it when forward-biased, as indicated by the portion of the curve on the positive vertical axis. (Vs = 0 V) • The forward current is determined by the bias voltage and the limiting resistor using Ohm's law. • (IF = VBIAS / RLIMIT ) • Since the reverse current is neglected, its value is assumed to be zero, as indicated in Figure by the portion of the curve on the negative horizontal axis. (IR = 0 A) • The reverse voltage equals the bias voltage. • VR = VBIAS

  6. Practical Diode Model • The practical model adds the barrier potential to the ideal switch model. • When the diode is forward-biased, it is equivalent to a closed switch in series with a small equivalent voltage source equal to the barrier potential (0.7 V) with the positive side toward the anode, as indicated in Figure (a). • This equivalent voltage source represents the fixed voltage drop (VF ) produced across the forward-biased pn junction of the diode and is not an active source of voltage.

  7. When the diode is reverse-biased. it is equivalent to an open switch just as in the ideal model, as shown in Figure (b). • The barrier potential does not affect reverse bias. so it is not a factor. • The characteristic curve for the practical diode model is shown in Figure. • Since the barrier potential is included and the dynamic resistance is neglected, the diode is assumed to have a voltage across it when forward-biased, as indicated by the portion of the curve to the right of the origin. • VF = 0.7 V

  8. The forward current is determined as follows by first applying Kirchhoff's voltage law to Figure (a)

  9. The Complete Diode Model • The complete model of a diode consists of the barrier potential, the small forward dynamic resistance (r’d), and the large internal reverse resistance (r’R). • The reverse resistance is taken into account because it provides a path for the reverse current, which is included in this diode model. • When the diode is forward-biased, it acts as a closed switch in series with the barrier potential voltage and the small forward dynamic resistance (r’d), as indicated in Figure (a). • When the diode is reverse-biased, it acts as an open switch in parallel with the large internal reverse resistance (r’R ), as shown in Figure (b). • The barrier potential does not affect reverse bias, so it is not a factor.

  10. The characteristic curve for the complete diode model is shown in Figure (c). • Since the barrier potential and the forward dynamic resistance are included, the diode is assumed to have a voltage across it when forward-biased. • This voltage (VF) consists of the barrier potential voltage plus the small voltage drop across the dynamic resistance, as indicated by the portion of the curve to the right of the origin. • The curve slopes because the voltage drop due to dynamic resistance increases as the current increases. • The reverse current is taken into account with the parallel resistance and is indicated by the portion of the curve to the left of the origin. • The breakdown portion of the curve is not shown because breakdown is not a normal mode of operation for most diodes • For the complete model of a silicon diode, the following formulas apply:

  11. Example 1 • Determine the forward voltage and forward current for the diode in Figure for each of the diode models. Also find the voltage across the limiting resistor in each case. Assume r’d=10 Ω at the determined value of forward current.

  12. Solution

  13. Example 2 • Determine the reverse voltage and reverse current for the diode in Figure for each of the diode models. Also find the voltage across the limiting resistor in each case. Assume lR = I µA.

  14. Solution

  15. Some Diodes

  16. Resistance of Diode

  17. Resistance of Diode • As the operating point of a diode moves from one region to another the resistance of the diode will also change due to the nonlinear shape of the characteristic curve. • There are two types of resistance • DC or static resistance • AC or dynamic resistance

  18. DC or Static Resistance • The application of a dc voltage to a circuit containing a semiconductor diode will result in an operating point on the characteristic curve that will not change with time. • The resistance of the diode at the operating point can be found simply by finding the corresponding levels of VDand IDas shown in Fig. and applying the equation: RD = VD / ID • The dc resistance levels at the knee and below will be greater than the resistance levels obtained for the vertical rise section of the characteristics. • The resistance levels in the reverse-bias region will naturally be quite high. • Since ohmmeters typically employ a relatively constant-current source, the resistance determined will be at a preset current level (typically, a few milliamperes). In general, therefore, the lower the current through a diode the higher the dc resistance level.

  19. Example 3. Determine the dc resistance levels for the diode of Fig. at (a) ID = 2 mA (b) ID= 20 mA (c) VD =-10 V

  20. AC or Dynamic Resistance • dc resistance of a diode is independent of the shape of the characteristic in the region surrounding the point of interest • If a sinusoidal rather than dc input is applied, the situation will change completely. • The varying input will move the instantaneous operating point up and down a region of the characteristics and thus defines a specific change in current and voltage as shown in Fig. • With no applied varying signal, the point of operation would be the Q-point appearing on Fig. determined by the applied dc levels. • The designation Q-point is derived from the word quiescent, which means “still or unvarying.”

  21. A straight line drawn tangent to the curve through the Q-point as shown in Fig. will define a particular change in voltage and current that can be used to determine the ac or dynamic resistance for this region of the diode characteristics. • An effort should be made to keep the change in voltage and current as small as possible and equidistant to either side of the Q-point. • In equation form, • The steeper the slope, the less the value of Vd for the same change in Id and the less the resistance. • The ac resistance in the vertical rise region of the characteristic is therefore quite small, while the ac resistance is much higher at low current levels. In general, therefore, the lower the Q-point of operation (smaller current or lower voltage) the higher the ac resistance.

  22. Voltage Current Characteristics of Diode

  23. Voltage Current Characteristics of Diode • Voltage current characteristics is the relation between voltage and current during the operation of a diode. • Voltage current characteristics will be different for • Forward biased characteristics • Reverse biased characteristics

  24. Forward Biased Diode • With 0 voltage there will be no current. • If forward voltage is gradually increased, diode voltage will increase until it reaches 0.7 V (Barrier potential). Then forward current begins to increase rapidly. • If voltage is further increased then current will increase accordingly but diode voltage will increase slightly. • This increase in diode voltage is due to voltage drop across the internal dynamic resistance of the semiconductor material.

  25. The diode forward voltage (VF ) increases to the right along the horizontal axis, and the forward current (IF) increases upward along the vertical axis. • The forward current increases very little until the forward voltage across the pn junction reaches approximately 0.7 V at the knee of the curve. • After this point. the forward voltage remains at approximately 0.7 V, but IF increases rapidly. • There is a slight increase in VF above 0.7 V as the current increases due mainly to the voltage drop across the dynamic resistance. • Normal operation for a forward-biased diode is above the knee of the curve. • The IF scale is typically in mA, as indicated.

  26. Effect of dynamic resistance • Unlike a linear resistance, the resistance of the forward-biased diode is not constant over the entire curve because the resistance changes as you move along the V-I curve, it is called dynamic or ac resistance. • Internal resistances of electronic devices are usually designated by lowercase italic r ’, instead of the standard R. • The dynamic resistance of a diode is designated rd’ • Below the knee of the curve the resistance is greatest because the current increases very little for a given change in voltage rd’ = ∆VF/ ∆IF • The resistance begins to decrease in the region of the knee of the curve and becomes smallest above the knee where there is a large change in current for a given change in voltage.

  27. Reverse Biased diode • When a reverse-bias voltage is applied across a diode, there is only an extremely small reverse current (IR) through the pn junction. • With 0 V across the diode. there is no reverse current. • As you gradually increase the reverse-bias voltage, there is a very small reverse current and the voltage across the diode increases. • When the applied bias voltage is increased to a value where the reverse voltage across the diode (VR ) reaches the breakdown value (VBR ). the reverse current begins to increase rapidly. • If reverse voltage is increased further, the current continues to increase very rapidly. but the voltage across the diode increases very little above VBR. • Breakdown, with exceptions, is not a normal mode of operation for most pn junction diodes.

  28. The diode reverse voltage (VR ) increases to the left along the horizontal axis, and the reverse current (IR) increases downward along the vertical axis. • There is very little reverse current (usually μA or nA) until the reverse voltage across the diode reaches approximately the breakdown value (VBR ) at the knee of the curve. • After this point, the reverse voltage remains at approximately VBR , but IR increases very rapidly, resulting in overheating and possible damage. • The breakdown voltage for a typical silicon diode can vary, but a minimum value of 50 V is not unusual.

  29. Effect of temperature • For a forward-biased diode, as temperature is increased. the forward current increases for a given value of forward voltage. • Also, for a given value of forward current, the forward voltage decreases. • This is shown with the V-I characteristic curves in Figure. • The blue curve is at room temperature (25°C) and the red curve is at an elevated temperature (25°C + ∆T). • Barrier potential decreases as temperature increases. • For a reverse-biased diode, as temperature is increased, the reverse current increases. • Reverse current below breakdown remains extremely small and can usually be neglected,

  30. Reverse Recovery Time • There are certain pieces of data that are normally provided on diode specification sheets provided by manufacturers. • One such quantity that has not been considered yet is the reverse recovery time, denoted by trr . • In the forward-bias state it was shown earlier that there are a large number of electrons from the n-type material progressing through the p-type material and a large number of holes in the n-type is a requirement for conduction. • The electrons in the p-type and holes progressing through the n-type material establish a large number of minority carriers in each material. • If the applied voltage should be reversed to establish a reverse-bias situation, we would ideally like to see the diode change instantaneously from the conduction state to the non-conduction state. • However, because of the large number of minority carriers in each material, the diode current will simply reverse as shown in Fig. and stay at this measurable level for the period of time ts(storage time) required for the minority carriers to return to their majority-carrier state in the opposite material. • In essence, the diode will remain in the short-circuit state with a current Ireverse determined by the network parameters.

  31. Eventually, when this storage phase has passed, the current will reduce in level to that associated with the non-conduction state. • This second period of time is denoted by tt(transition interval). • The reverse recovery time is the sum of these two intervals: trr= ts +tt. • Naturally, it is an important consideration in high speed switching applications. • Most commercially available switching diodes have a trrin the range of a few nanoseconds to 1 s. • Units are available, however, with a trr of only a few hundred picoseconds (10-12)

  32. Testing a Diode • A multimeter can be used as a fast and simple way to check a diode. • A good diude will show an extremely high resistance (ideally an open) with reverse bias and a very low resistance with forward bias. • A defective open diode will show an extremely high resistance (or open) for both forward and reverse bias. • A defective shorted or resistive diode will show zero or a low resistance for both forward and reverse bias. • An open diode is. the most common type of failure.

  33. The DMM Diode Test Position • Many digital multimeters (DMMs) have a diode test position that provides a convenient way to test a diode. • A typical DMM, has a small diode symbol to mark the position of the function switch. • When set to diode test. the meter provides an internal voltage sufficient to forward-bias and reverse-bias a diode. • This internal voltage may vary among different makes of DMM, but 2.5 V to 3.5 V is a typical range of values. • The meter provides a voltage reading or other indication to show the condition of the diode under test.

  34. When the Diode Is Working • In Figure (a), the red (positive) lead of the meter is connected to the anode and the black (negative) lead is connected to the cathode to forward-bias the diode. • If the diode is good, you will get a reading of between approximately 0.5 V and 0.9 V, with 0.7 V being typical for forward bias. • In Figure (b), the diode is turned around to reverse-bias the diode as shown. • If the diode is working properly, you will get a voltage reading based on the meter's internal voltage source. • The 2.6 V shown in the figure represents a typical value and indicates that the diode has an extremely high reverse resistance with essentially all of the internal voltage appearing across it.

  35. When the Diode Is Defective • When a diode has failed open. you get an open circuit voltage reading (2.6 V is typical) or "OL" indication for both the forward-bias and the reverse-bias condition, as illustrated in Figure (a). • If a diode is shorted, the meter reads 0 V in both forward- and reverse-bias tests, as indicated in figure (b). • Sometimes, a failed diode may exhibit a small resistance for both bias conditions rather than a pure short. • In this case, the meter will show a small voltage much less than the correct open voltage. • For example, a resistive diode may result in a reading of 1.1 V in both directions rather than the correct readings of 0.7 V for forward bias and 2.6 V for reverse bias.

  36. Checking a Diode with the OHMs Function • DMMs that do not have a diode test position can be used to check a diode by setting the function switch on an OHMs range. • For a forward-bias check of a good diode, you will get a resistance reading that can vary depending on the meter's internal battery. • Many meters do not have sufficient voltage on the OHMs setting to fully forward-bias a diode and you may get a reading of from several hundred to several thousand ohms, • For the reverse-bias check of a good diode, you will get some type of out-of-range indication such as "OL" on most DMMs because the reverse resistance is too high for the meter to measure.

  37. Even though you may not get accurate forward- and reverse-resistance readings on a DMM, the relative readings indicate that a diode is functioning properly, and that is usually all you need to know. • The out-of-range indication shows that the reverse resistance is extremely high, as you expect. • The reading of a few hundred to a few thousand ohms for forward bias is relatively small compared to the reverse resistance, indicating that the diode is working properly. • The actual resistance of a forward-biased diode is typically much less than 100Ω.

  38. Thanks

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