using both Parallelogram method (law of sines and cos) and Cartesian method (vector components) find final...

A) Using a x-y Cartesian coordinate system for reference depict the VECTOR POSITION for a projectile,...

A) Using a x-y Cartesian coordinate system for reference depict the VECTOR POSITION for a projectile, launched at an angle of 450 above the horizontal, at the highest point of the trajectory of the projectile. In addition, represent the x and y components of the vector position. B) Using a x-y Cartesian coordinate system for reference depict the VECTOR VELOCITY for a projectile, launched at an angle of 450 above the horizontal, at the highest point of the trajectory of...

2. Coulomb’s Law, multiple charges (10 pts) Charge ?1 = +25?? is at the origin, charge...

2. Coulomb’s Law, multiple charges (10 pts) Charge ?1 = +25?? is at the origin, charge ?2 = −15?? is on the x-axis at ? = 2.00 ?, and charge ?3 = +20?? is at the point ? = 2.00 ?, ? = 2.00 ?. a) Draw a labelled diagram of the charges and their locations. Include: • A coordinate system • Vector arrows for the forces due to each charge acting on charge ?3. • A vector arrow showing...

Find root of the equation cos (x) = xex using Bisection method. Make calculation for 4...

Find root of the equation cos (x) = xex using Bisection method. Make calculation for 4 iterations. Choose xl= 0 and xu= 1. Determine the approximate error in each iteration. Give the final answer in a tabular form.

1. Which describes the vector calculation of the Biot-Savart law?    a. The length element in...

1. Which describes the vector calculation of the Biot-Savart law?    a. The length element in the direction of the current is crossed into a vector directed from that element toward the point of measurement.    b. The length element in the direction of the current is dotted into a vector directed from that element toward the point of measurement.    c. The magnetic field vector is crossed into a vector directed from a current-length element toward the point of...

You and a group of friends are both too fast and too furious. After a series...

You and a group of friends are both too fast and too furious. After a series of capers, you attempt to steal a heavy safe by dragging it away using chains attached to two cars. The safe has a mass of 745 kg. The coefficient of friction between the asphalt and safe is µk = 0.11 Your car pulls toward the right, but your partner gets confused and is pulling to the left. It’s a tug-of-war! Your car applies a...

4. A pilot flying from Honolulu to California flies at an airspeed of 300.0 m/s (“airspeed”...

4. A pilot flying from Honolulu to California flies at an airspeed of 300.0 m/s (“airspeed” = airplane’s speed through the surrounding air) with her airplane pointed 70.0˚ to the east of north. However, the air itself is moving with a 50.0-m/s windspeed blowing due east. When the pilot adds together the two vectors of her airspeed and the windspeed, she gets her groundspeed: the airplane’s actual velocity relative to the ground below. (Even though these are called “speeds” by...

Your task will be to derive the equations describing the velocity and acceleration in a polar...

Your task will be to derive the equations describing the velocity and acceleration in a polar coordinate system and a rotating polar vector basis for an object in general 2D motion starting from a general position vector. Then use these expressions to simplify to the case of non-uniform circular motion, and finally uniform circular motion. Here's the time-dependent position vector in a Cartesian coordinate system with a Cartesian vector basis: ⃗r(t)=x (t) ̂ i+y(t) ̂ j where x(t) and y(t)...

Using the following code: % Ex 6.4 First-order step and impulse response for two time constants...

Using the following code: % Ex 6.4 First-order step and impulse response for two time constants % clear all; close all; t = 0:.1:100; % Time vector subplot(1,2,1); x = 250*exp(-0.05*t); plot(t,x,'k'); xlabel('Time (hrs)','FontSize',14); ylabel('P_A (mmHg)','FontSize',14); title('Impulse Response','FontSize',14); subplot(1,2,2); x = 20*(1-exp(-0.05*t)); plot(t,x,'k'); xlabel('Time (hrs)','FontSize',14); ylabel('P_A (mmHg)','FontSize',14); title('Step Response','FontSize',14);    ANSWER: The response of a 1st order linear body fluid balance system to step function (L m (t) = 1/s, Eqn. 6.9/p226) and impulse function (L d (t) = 1,...

Introduction Purpose Your goal is to create a design for a software interface. You will experience...

Introduction Purpose Your goal is to create a design for a software interface. You will experience the scope of the design process from brainstorming ideas and gathering information about users’ needs to storyboarding, prototyping, and finally, testing and refining your product. As you work on the software interface, you will demonstrate your ability to apply fundamental Human-Computer Interaction principles to interface analysis, design, and implementation. You will be responsible for delivering project components to your professor at several points during...

Please answer the following Case analysis questions 1-How is New Balance performing compared to its primary...

Please answer the following Case analysis questions 1-How is New Balance performing compared to its primary rivals? How will the acquisition of Reebok by Adidas impact the structure of the athletic shoe industry? Is this likely to be favorable or unfavorable for New Balance? 2- What issues does New Balance management need to address? 3-What recommendations would you make to New Balance Management? What does New Balance need to do to continue to be successful? Should management continue to invest...