Respuesta :
The closest answer would be C.
The choices given do not give the exact value.
To answer this, you just need to remember the main formula:
[tex]d = Vit + \frac{1}{2}gt^{2} [/tex]
Where:
d = distance/displacement
g = acceleration due to gravity
t = time in flight
Vi = initial velocity.
With this formula, you derive all the formulas you need to look for certain components. You need to keep in mind of the following:
---if you are looking for a vertical component(y), you need to use values of vertical motion.
[tex]dy = Viyt + \frac{1}{2}gt^{2} [/tex]
*Viy is always 0m/s at the beginning of a free-fall.
[tex]dy = (0m/s)t + \frac{1}{2}gt^{2} [/tex]
[tex]dy = \frac{1}{2}gt^{2} [/tex]
---If you are looking for a horizontal component(x), you need to use values of horizontal motion.
[tex]dx = Vixt + \frac{1}{2}gt^{2} [/tex]
*g is always 0m/s² when taking horizontal motion into account.
[tex]dx = Vixt + \frac{1}{2}(0m/s^{2})t^{2} [/tex]
[tex]dx = Vixt[/tex]
--- time is the only value that is both vertical and horizontal.
Okay, let's get back to solving your problem. Let's see what your given is first:
dy = 137m (as long as it refers to height, it is vertical distance)
dx = 4km (the word, far or away usually indicates horizontal distance)
g = 1.63m/s²
The question is how fast was it going horizontally and we can derive it from our equation:
[tex]dx = Vixt[/tex]
We use this because x means horizontal. But notice that we do not have time yet. So how are we going to solve this 2 variables missing? The key is that time is a horizontal and vertical component. Whatever time it took moving horizontally, it is the same vertically as well. So we use the vertical formula to derive time:
[tex]dy = \frac{1}{2}gt^{2} [/tex]
[tex]\frac{2dy}{g}=t^{2} [/tex]
[tex] \sqrt{\frac{2dy}{g}} = \sqrt{t^{2}} [/tex]
[tex] \sqrt{\frac{2dy}{g}} = t [/tex]
Now plug in what you know and solve for what you don't know:
[tex] \sqrt{\frac{2(137m)}{1.63m/s^{2}}} = t [/tex]
[tex] \sqrt{\frac{274m}{1.63m/s^{2}}} = t [/tex]
[tex] \sqrt{168.098s^{2}}=t[/tex]
[tex] 12.965s = t [/tex]
The total time in flight is 12.965s.
Let's round it off to 13s.
Now that we know that, we can use this in the horizontal formula:
[tex]dx = Vixt[/tex]
[tex]4km = Vix(13s)[/tex]
Hold up! Look at the unit of the horizontal distance. It is in km but all our units are expressed in m so we need to convert that first.
1km = 1,000m
4km = 4,000m
Our new horizontal distance is 4,000m.
Okay, let's wrap this up by solving for what is asked for, using all the derived values.
[tex]dx = Vixt[/tex]
[tex]4,000m = Vix(13s)[/tex]
[tex]\frac{4,000m}{13s} = Vix[/tex]
[tex] 308m/s= Vix[/tex]
The horizontal velocity is 308m/s.
Such a long explanation I know, but hopefully, you learned from it.
The choices given do not give the exact value.
To answer this, you just need to remember the main formula:
[tex]d = Vit + \frac{1}{2}gt^{2} [/tex]
Where:
d = distance/displacement
g = acceleration due to gravity
t = time in flight
Vi = initial velocity.
With this formula, you derive all the formulas you need to look for certain components. You need to keep in mind of the following:
---if you are looking for a vertical component(y), you need to use values of vertical motion.
[tex]dy = Viyt + \frac{1}{2}gt^{2} [/tex]
*Viy is always 0m/s at the beginning of a free-fall.
[tex]dy = (0m/s)t + \frac{1}{2}gt^{2} [/tex]
[tex]dy = \frac{1}{2}gt^{2} [/tex]
---If you are looking for a horizontal component(x), you need to use values of horizontal motion.
[tex]dx = Vixt + \frac{1}{2}gt^{2} [/tex]
*g is always 0m/s² when taking horizontal motion into account.
[tex]dx = Vixt + \frac{1}{2}(0m/s^{2})t^{2} [/tex]
[tex]dx = Vixt[/tex]
--- time is the only value that is both vertical and horizontal.
Okay, let's get back to solving your problem. Let's see what your given is first:
dy = 137m (as long as it refers to height, it is vertical distance)
dx = 4km (the word, far or away usually indicates horizontal distance)
g = 1.63m/s²
The question is how fast was it going horizontally and we can derive it from our equation:
[tex]dx = Vixt[/tex]
We use this because x means horizontal. But notice that we do not have time yet. So how are we going to solve this 2 variables missing? The key is that time is a horizontal and vertical component. Whatever time it took moving horizontally, it is the same vertically as well. So we use the vertical formula to derive time:
[tex]dy = \frac{1}{2}gt^{2} [/tex]
[tex]\frac{2dy}{g}=t^{2} [/tex]
[tex] \sqrt{\frac{2dy}{g}} = \sqrt{t^{2}} [/tex]
[tex] \sqrt{\frac{2dy}{g}} = t [/tex]
Now plug in what you know and solve for what you don't know:
[tex] \sqrt{\frac{2(137m)}{1.63m/s^{2}}} = t [/tex]
[tex] \sqrt{\frac{274m}{1.63m/s^{2}}} = t [/tex]
[tex] \sqrt{168.098s^{2}}=t[/tex]
[tex] 12.965s = t [/tex]
The total time in flight is 12.965s.
Let's round it off to 13s.
Now that we know that, we can use this in the horizontal formula:
[tex]dx = Vixt[/tex]
[tex]4km = Vix(13s)[/tex]
Hold up! Look at the unit of the horizontal distance. It is in km but all our units are expressed in m so we need to convert that first.
1km = 1,000m
4km = 4,000m
Our new horizontal distance is 4,000m.
Okay, let's wrap this up by solving for what is asked for, using all the derived values.
[tex]dx = Vixt[/tex]
[tex]4,000m = Vix(13s)[/tex]
[tex]\frac{4,000m}{13s} = Vix[/tex]
[tex] 308m/s= Vix[/tex]
The horizontal velocity is 308m/s.
Such a long explanation I know, but hopefully, you learned from it.
