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Required information Consider the given instrumentation amplifier with the resistance values R1 = 27 kΩ, R2 = 93 kΩ, R3 = 34 kΩ, and R4 = 50 kΩ. What is the output voltage if v1 = (4 − 0.2sin⁡4,000πt) V and v2 = 3.5 V? Multiple Choice vO = (−5.42 + 1.25sin⁡4,000π) V vO = (5.42 − 1.25sin⁡4,000π) V vO = (−5.5 + 1.90sin⁡4,000π) V vO = (5.5 − 1.90sin⁡4,000π) V vO = (−7.63 + 3.3sin⁡4,000π) V vO = (−3.27 + 1.308sin⁡4000π) V

Required information Consider the given instrumentation amplifier with the resistance values R1 = 27 kΩ, R2 = 93 kΩ, R3 = 34 kΩ, and R4 = 50 kΩ. What is the output voltage if v1 = (4 − 0.2sin⁡4,000πt) V and v2 = 3.5 V? Multiple Choice vO = (−5.42 + 1.25sin⁡4,000π) V vO = (5.42 − 1.25sin⁡4,000π) V vO = (−5.5 + 1.90sin⁡4,000π) V vO = (5.5 − 1.90sin⁡4,000π) V vO = (−7.63 + 3.3sin⁡4,000π) V vO = (−3.27 + 1.308sin⁡4000π) V

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! Required information Consider the given instrumentation amplifier with the resistance values R 1 = 27 k Ω , R 2 = 93 k Ω , R 3 = 34 k Ω , and R 4 = 50 k Ω .
What is the output voltage if v 1 = ( 4 0.2 sin 4 , 000 π t ) V and v 2 = 3.5 V ?
Multiple Choice v O = ( 5.42 + 1.25 sin 4 , 000 π ) V v O = ( 5.42 1.25 sin 4 , 000 π ) V v O = ( 5.5 + 1.90 sin 4 , 000 π ) V v O = ( 5.5 1.90 sin 4 , 000 π ) v O = ( 7.63 + 3.3 sin 4 , 000 π ) V v O = ( 3.27 + 1.308 sin 4000 π ) V

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