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Moldflow Monday Blog

Electrical Engineering Fundamentals By Vincent Del Toro Pdf | Desktop |

Learn about 2023 Features and their Improvements in Moldflow!

Did you know that Moldflow Adviser and Moldflow Synergy/Insight 2023 are available?
 
In 2023, we introduced the concept of a Named User model for all Moldflow products.
 
With Adviser 2023, we have made some improvements to the solve times when using a Level 3 Accuracy. This was achieved by making some modifications to how the part meshes behind the scenes.
 
With Synergy/Insight 2023, we have made improvements with Midplane Injection Compression, 3D Fiber Orientation Predictions, 3D Sink Mark predictions, Cool(BEM) solver, Shrinkage Compensation per Cavity, and introduced 3D Grill Elements.
 
What is your favorite 2023 feature?

You can see a simplified model and a full model.

For more news about Moldflow and Fusion 360, follow MFS and Mason Myers on LinkedIn.

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Problem 9 — Practical measurement & instrumentation (15 pts) You must measure a small AC voltage (peak 20 mV) in presence of large common-mode interference (~10 V) using an instrumentation amplifier built from op-amps. a) (6 pts) Sketch the schematic conceptually (describe stages: input filtering, INA, gain, common-mode rejection). b) (5 pts) Choose an INA gain to get ~2 V full-scale output and compute resistor values or gain-setting component. c) (4 pts) List three practical techniques to maximize CMRR and reduce noise in this measurement.

Part C — Design, analysis & applications (50 pts) Problem 7 — Filter synthesis & Bode (20 pts) Design a second-order Butterworth low-pass filter with cutoff fc = 1 kHz using an active Sallen–Key topology with unity gain buffer. Use standard component values within a factor of two. a) (6 pts) Provide component values (R1, R2, C1, C2) and show normalized component selection for Butterworth (Q=0.707). b) (6 pts) Derive the transfer function H(s) and show the -3 dB cutoff condition. c) (8 pts) Sketch (or describe numerically) magnitude Bode plot points at 10 Hz, 100 Hz, 1 kHz, 10 kHz, and 100 kHz (provide gains in dB).

Problem 5 — Op-amp design (15 pts) Design an inverting amplifier with gain -10 using a real op-amp whose open-loop gain Aol(s) ≈ 10^5/(1 + s/2π·10 Hz). a) (6 pts) Choose Rf and Rin values (standard decade resistances) to realize the closed-loop midband gain -10 and justify choice. b) (5 pts) Compute the closed-loop bandwidth approximately using op-amp open-loop dominant pole. c) (4 pts) Discuss one stability concern with using very large feedback capacitances in the feedback network.