1) Consider the circuit at right, consisting of two R LEDS (one red, one green), which you can model as “practical diodes" with VD= 2.0V (LEDS typically have larger Vp's than ordinary Si or Ge diodes). red green в a) If terminals A and B were connected to a DC source with voltage Vo, what would happen? (Consider applying in both polarities, i.e. +Vo and –Vo, and when VoVp...) b) If the terminals A and B were connected to an AC source with peak voltage V0, what would happen? (Consider both very low frequency: f<~1 Hz – and high-frequency cases.) c) If R = 1 k2, and both diodes have a maximum continuous power dissipation of 0.1 W and a peak inverse voltage Vpiv = 20V, what is the maximum DC voltage VDCmax Which can be safely applied between A and B?

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A 1) Consider the circuit at right, consisting of two LEDS (one red, one green), which you can model as “practical diodes" with VD= 2.0V (LEDS typically have larger VD's than ordinary Si or Ge diodes). R red green B a) If terminals A and B were connected to a DC source with voltage Vo, what would happen? (Consider applying in both polarities, i.e. +Vo and –Vo, and when Vo<Vp and Vo>VD...) b) If the terminals A and B were connected to an AC source with peak voltage VO, what would happen? (Consider both very low frequency: f<~1 Hz – and high-frequency cases.) c) If R = 1 k2, and both diodes have a maximum continuous power dissipation of 0.1 W and a peak inverse voltage VPIV = 20V, what is the maximum DC voltage VDCmax which can be safely applied between A and B?