Gork@lemm.ee to Lemmy Shitpost@lemmy.world · 7 months agoLet π = 5files.catbox.moeimagemessage-square72fedilinkarrow-up1116arrow-down13cross-posted to: [email protected]
arrow-up1113arrow-down1imageLet π = 5files.catbox.moeGork@lemm.ee to Lemmy Shitpost@lemmy.world · 7 months agomessage-square72fedilinkcross-posted to: [email protected]
minus-squareFiniteBanjo@lemmy.todaylinkfedilinkarrow-up5·edit-27 months agoI would be a smartass and leave Pi as a factor throughout and in the answer. I’m used to doing that in Calculus anyways. V = πr2h V = π⋅102⋅10 V = π⋅100⋅10 V = π1000 BONUS SOLUTION: V =∫010 A⋅h dh A = ∫010 2πr dr V= ∫010 ∫010 h⋅2πr dr dh h is a constant for A’s integral so we can safely move it into V’s integral V= ∫010 h⋅∫010 2πr dr dh π is a constant so we can safely remove it from A’s integral A = π⋅∫010 2r dr A = π⋅[r2]010 A = π⋅( [102] - [02] ) A = π102 A = π100 V = ∫010 h⋅π100 dh π100 is a constant so we can safely remove it from V’s integral V = π100⋅∫010 h dh V = π100⋅[h]010 V = π100⋅([10] - [0]) V = π100⋅10 V = π1000 It goes a lot deeper but I’m not bored enough for that, yet. EDIT: Hang on. I’m wrong with that height integral. Can somebody help remind me?
minus-squarebenignintervention@lemmy.worldlinkfedilinkarrow-up3·7 months agoIf you really wanted to be through you’d start at a point, integrate out along dr for a line, then integrate in a circle through dtheta to derive the area before doing the rest
I would be a smartass and leave Pi as a factor throughout and in the answer. I’m used to doing that in Calculus anyways.
V = πr2h
V = π⋅102⋅10
V = π⋅100⋅10
V = π1000
BONUS SOLUTION:
V =∫010 A⋅h dh
A = ∫010 2πr dr
V= ∫010 ∫010 h⋅2πr dr dh
h is a constant for A’s integral so we can safely move it into V’s integral
V= ∫010 h⋅∫010 2πr dr dh
π is a constant so we can safely remove it from A’s integral
A = π⋅∫010 2r dr
A = π⋅[r2]010
A = π⋅( [102] - [02] )
A = π102
A = π100
V = ∫010 h⋅π100 dh
π100 is a constant so we can safely remove it from V’s integral
V = π100⋅∫010 h dh
V = π100⋅[h]010
V = π100⋅([10] - [0])
V = π100⋅10
V = π1000
It goes a lot deeper but I’m not bored enough for that, yet.
EDIT: Hang on. I’m wrong with that height integral. Can somebody help remind me?
If you really wanted to be through you’d start at a point, integrate out along dr for a line, then integrate in a circle through dtheta to derive the area before doing the rest