Given the hourehild poue Shown, d In on izov 1a.3 Given the hourehild poue Shown, d In on izov 1a.3
3, Given the circuit shown in Figure 3. a) Find the current in the 14 volt battery b) Find the .potential differece Va . 20V 3.0 1A F. g, 3
1a) Consider the elbow joint pictured. Given that the muscle connection distance is d=1.29 cm and the barbell mass is M=7.0 kg, find the muscle tension force? 3552 ✓N muscle tension F E distance d barbel in hand 555cm long, 3 kg rod b) What is the rotational inertia of the arm/barbell system? 2.42 kgm? c) If the arm begins at rest and accelerates through 45° in 303 millseconds, find the angular acceleration: rad/s2 Check d) What muscle tension will...
1a). Consider the equation ay" + by' + cy = d where d ∈ R and a, b and c are positive constants. Show that any solution of this equation approaches d/c as x → +∞. That is, given y(x) a solution we have lim y(x) as x → +∞ = d/c . 1b.) What happens if c = 0? 1c.) What about the case where b = c = 0?
Question # 3 R1 10 1A R2 10Ω V2 10V For the circuit shown in the above figure: 1) Calculate the voltage across the current source. 2) Calculate the current in the voltage source. 3) Determine which source is discharging (delivering power) and which is charging (receiving power). Prove that the power is balanced in the above circuit. Calculate the energy dissipated by the resistor R2 (10 Ω) in 20 seconds. 4)
1a) Mesh Analysis [ 5 marks ] Consider the circuit shown below. All resistances are in Ohms. 8 v1 592 + + V1 422 7V2 3 Ω 5 V 2 Ω iz V2 + 622 10 22 i) Write down the KVL in the super mesh based on the mesh currents (ii, i2 and i3) given on the circuit. Do not solve the equations. [2 marks ] ii) Write down other equations in terms of mesh currents (ii, i2 and...
Problem 1. Given the 3-D sketch as shown of a tripod stand with a 300 ft"lb moment applied to the top at D (applied by a wrench). The tripod base is an equilateral triangle with 2 ft on each side. The height of the stand is 4 ft. Find the Resultant Force at points A, B, and C. The moment at D is in a parallel plane to the plane A, B and C are in. D 300 ft*lb h=4ft...
LABORATORY XI: MOLECULAR GEOMETRY AND BONDING I-THE NITTY GRITTY C. LEWIS DOT STRUCTURE 1A. NAME (given for informational purposes only B. MOLECULAR FORMULA Carbon tetrachloride CCL D. VSEPR SKETCH E. GEOMETRIES F. ANOTHER DEPICTION (shown only for illustration purposes) https:/en.wikipedia.org/wiki/Carbon tetrachloride Electron-domain (parent): Molecular: 2A. NAME (given for informational purposes only) B. MOLECULAR FORMULA C. LEWIS DOT STRUCTURE Phosphorus Trichloride richloride PCI D. VSEPR SKETCH E. GEOMETRIES F. ANOTHER DEPICTION (shown only for illustration purposes) https://en.wikipedia.org/wiki/Phosp horus trichloride Electron-domain (parent):...
The overhanging beam in Figure 1a has the T-shaped cross section shown in Figure 1b. Determine the values and locations of the maximum tensile and compressive bending stresses. 20 kN 20 kN/m 45° 7 3 m Figure 1a 200 mm I 20 mm 200 mm 20 mm Figure 1b
The schematic circuit of a noninverting amplifier is shown in Fig.1aThe circuit specifications are: V1=0.1V Again=30dB R3=100kΩ R1=10kΩ(a) Determine the output voltage of the amplifier, assume the op-amp is ideal.(b) Determine the resistance of R2, assume the op-amp is ideal.(c) Does the value of R1 affect the output of the amplifier, if the op-amp is
ideal? Justify your answer.(d) Does the value of R1 affect the output of the amplifier, if the op-amp is
non-ideal and has only an input offset voltage shown in...
6. The displacement (D) of a wave on a string is shown for a given location of the wave on the string, using this graph, period, wavelength, and frequency of the wave: D (cm) -3 0.2 04 06 0.8 h0 History graph at x 0 m Wave traveling left at 2.0 m/s