10ΩwwQ2) Simplify the circuit by combining the series and parallel components.(+1)1.5 VR₂R₁≤2202Vsi12 VΩV$2$1R RR47 2 0.5 AΩ15 92 0.25 A68 0.75 AR₁(+1)www6 V33 Ω

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Answered: 10 Ω ww Q2) Simplify the circuit by…

Delmar's Standard Textbook Of Electricity

7th Edition

ISBN:9781337900348

Author:Stephen L. Herman

Publisher:Stephen L. Herman

Chapter23: Resistive-inductive-capacitive Series Circuits

Section: Chapter Questions

Problem 6RQ

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+5V VDO EN Xtal 8ה 7 +5V Freq1 HGND | GND х Mhz Sensor0 crystal Freq26 5 Vss Out 04 PRE Xtal 1k Output HA7210IP 4 CLK CLR SN74HC7491 GND 0.01 μ GND +5V 4 +5V +5V +5V OE O/P3 0. 1µF | 47µF GND SG351P |2 x MHz GND GND Consider the Quartz Crystal Microbalance Sensor shown above, with crystal resonant frequency, x = 3.3 Mhz. You are given the following values: Active crystal area = 1.6 cm², and the change in frequency = - 10 Hz Calculate the change in mass, Am in nano gram, up to 2 decimal places. Answer:

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10 Ω ww Q2) Simplify the circuit by combining the series and parallel components. (+1) 1.5 V R₂ R₁≤2202 Vsi 12 V Ω V$2 $1 R RR 47 2 0.5 A Ω 15 92 0.25 A 68 0.75 A R₁ (+1) www 6 V 33 Ω