Comments
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My team matrix [0,2,0,1,2,1,0,2], [1,0,1,2,1,0,2,2], [2,2,0,2,2,2,2,2], [2,1,0,0,1,2,2,2], [0,2,0,2,0,1,1,0], [2,2,1,1,2,0,2,2], [2,1,1,0,2,1,0,2], [0,1,0,0,2,0,0,0] Team 3: rating = 0.5330684574735053 Team 6: rating = 0.44328808110881446 Team 4: rating = 0.3658903880213609 Team 2: rating = 0.3361884024157472 Team 7:…
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With no external heat source this is what my bar looks like in a steady state. at the vertex denoted by (30,0) the heat is about .947 in the steady state
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The temperature of the midpoint at the insulated edge at t=1s is 1.91ish as shown in the image below.
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My dude just looks like he is super embarrassed to be on fire.
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A metal bar of length 1 lies along the unit interval. Its temperature distribution is given by $g(x) = 4x^2 - 1x$ At time t=0, its left end is set to temperature 3 and its right end to -3. Sketch the temperature distribution at times t=0,t=0.01,t=0.1, and t=10.
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So I am still confused over whether this graph is supposed to be just qualitative. I feel like I am missing a diffusivity constant if I wanted a more precise understanding of what my graph looks like at specific times.
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$u_t=u_x{}_x+8 ,u(0,t)=-4 ,u(1,t)=4$ since we are looking for a steady state we are looking for when $$u_t=0$$ because our equation should not change with respect to time. By looking at our first equation we integrate up $$u_x{}_x$$ and net $$u=-4x^2+Ax+B$$ with A and B being some constants. We then solve for A and B using…
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The distance of the midpoint from the equilibrium at time t=1.3 is approximately .265