o1.) Suppose you had the BJT circuit below as part of a system that only operates correctly when the BJT has a specific Q point values (Icq and VCEQ), for example we'll see that BJT amplifier performance is a strong function of the Q-point. Solve the for the circuit's Q-point values (Ico and VCEQ) assuming a) ß =150, and b) ß =100. Comment on whether you think this circuit would be a good choice if used in mass production scenario. (hint: recall that ß is a device parameter...). 9 12v 2k Vв 565k

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**Transcription for Educational Website:** --- **Understanding Q-Point in BJT Circuits** 1. **Scenario Analysis for BJT Circuits:** Suppose you have the BJT (Bipolar Junction Transistor) circuit shown below as part of a system that performs correctly only when the BJT has specific Q-point values (\(I_{CQ}\) and \(V_{CEQ}\)). It is crucial as BJT amplifier performance is highly dependent on the Q-point. Your task is to solve for the circuit’s Q-point values (\(I_{CQ}\) and \(V_{CEQ}\)) under the following assumptions: a) \(\beta = 150\) b) \(\beta = 100\) Additionally, evaluate whether this circuit design would be suitable for mass production. (Hint: Remember, \(\beta\) is a device parameter that may vary.) 2. **Circuit Diagram Explanation:** - The circuit consists of a BJT connected with a 2k ohm resistor in the collector line linked to a 12V supply. - The base is connected through a 565k ohm resistor connected to a base voltage (\(V_B\)) source. - The emitter is grounded. Evaluate these conditions considering that \(\beta\) may vary among individual transistors, which can impact production consistency. ---