final speed of the 3.0 kg cart is 2.67 m/s .
<u>Step-by-step explanation:</u>
Here we have , A 2.0 kg cart moving right at 5.0 on a friction less track collides with a 3.0 kg cart initially at rest. The 2.0 kg cart has a final speed of 1.0 to the left. We will use law of conservation of momentum: For a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision.
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Therefore, final speed of the 3.0 kg cart is 2.67 m/s .
(2,13),(5,22)
slope = (22 - 13) / (5 - 2) = 9/3 = 3
y = mx + b
slope(m) = 3
use either of ur points...(2,13)...x = 2 and y = 13
now sub and find b, the y int
13 = 3(2) + b
13 = 6 + b
13 - 6 = b
7 = b
so ur equation is : y = 3x + 7 <===
Answer:
The answer to your question is y-intercept = 22, slope = -6
Step-by-step explanation:
- To find the answer you need to find the equation of the line.
Process
1.- Find the slope
slope = m = (y2 - y1) / (x2 - x1)
x1 = 2 y1 = 10 x2 = 3 y2 = 4
-Substitution
m = (4 - 10) / (3 - 2)
-Simplifying
m = -6/1
-Result
m = -6
2.- Find the equation of the line
y - y1 = m(x - x1)
-Substitution
y - 10 = -6(x - 2)
-Simplifying
y - 10 = -6x + 12
y = -6x + 12 + 10
-Result
y = -6x + 22
3.- Conclusion
y-intercept = 22
slope = -6
Answer:
The statement of the fundamental theorem of calculus shows the upper limit of the integral as exactly the variable of differentiation. Using the chain rule in combination with the fundamental theorem of calculus we may find derivatives of integrals for which one or the other limit of integration is a function of the variable of differentiation.
Step-by-step explanation:
