Homework 4
... 3. The steel ingot shown in Fig. 2 has a mass of 1800 kg. It travels along the conveyor at a speed v = 0.5 m/s when it collides with the nested spring assembly. Determine the maximum deflections in each spring needed to stop the motion of the ingot, if kA = 5 kN/m and kB = 3 kN/m. (10 points) 4. The ...
... 3. The steel ingot shown in Fig. 2 has a mass of 1800 kg. It travels along the conveyor at a speed v = 0.5 m/s when it collides with the nested spring assembly. Determine the maximum deflections in each spring needed to stop the motion of the ingot, if kA = 5 kN/m and kB = 3 kN/m. (10 points) 4. The ...
Exam Window
... Write a system of equations in x and y describing the situation. Do not solve the system. 14) One number is 5 more than another number. If you add 8 to 2 times the first number, the result is 3 times the second number. ...
... Write a system of equations in x and y describing the situation. Do not solve the system. 14) One number is 5 more than another number. If you add 8 to 2 times the first number, the result is 3 times the second number. ...
Page 1 Grade 8 Math Reference Sheet Add Subtract Multiply Divide
... 1. Find all factors of each number. 2. Circle common factors. 3. Find the greatest (largest #) in common. That is the Greatest Common Factor. ...
... 1. Find all factors of each number. 2. Circle common factors. 3. Find the greatest (largest #) in common. That is the Greatest Common Factor. ...
Concurrency Worksheet
... Step 2: Using your compass, measure the distance from the circumcenter to point A. Then measure the distance from the circumcenter to point B. Do the same for point C. What do you notice? _______________________________________________________________________________________ ________________________ ...
... Step 2: Using your compass, measure the distance from the circumcenter to point A. Then measure the distance from the circumcenter to point B. Do the same for point C. What do you notice? _______________________________________________________________________________________ ________________________ ...
Weber problem
In geometry, the Weber problem, named after Alfred Weber, is one of the most famous problems in location theory. It requires finding a point in the plane that minimizes the sum of the transportation costs from this point to n destination points, where different destination points are associated with different costs per unit distance.The Weber problem generalizes the geometric median, which assumes transportation costs per unit distance are the same for all destination points, and the problem of computing the Fermat point, the geometric median of three points. For this reason it is sometimes called the Fermat–Weber problem, although the same name has also been used for the unweighted geometric median problem. The Weber problem is in turn generalized by the attraction–repulsion problem, which allows some of the costs to be negative, so that greater distance from some points is better.