# Tag Info

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(a-b)*(a-b) is the right answer. the only one? I guess so!

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Interesting question. As you're no doubt well aware, firstly you're trying to solve 4 equations in 3 independent variables. This is only possible when the 4th equation can be deduced from the first 3. Secondly the square part of the system - the first 3 equations (rows) are degenerate, with zero determinant - try det(A(1:3,:)) So what's the numerical ...

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Let's say A' = D so when A is false, then D is true and vice versa. Then A' + AB = D + D'B and if you understand your first equation: D + D'B = D + B = A' + B Regarding your comment: I'll use this equality: AB + A'B = B and I will combine the first with the third and the second with the fifth term: x'y'z'+x'yz+xy'z'+xy'z+xyz = y'z' + yz + xy'z Now, ...

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Don't forget, you can also push ASCII values!! Usually, this is longer, but for higher numbers it can get much shorter: If you needed the number 123, it would be much better to do "{" than 99*76*+

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There's a problem on this line: m--; for(i = 0; i < n; i++) { m[i]--; } You're decrementing m, but then go ahead and index it from 0 ... I guess you may end up messing up the heap structures. I managed to have your code valgrind error-free like this: #include <stdio.h> #include <string.h> #include <stdlib.h> int main(int argc, ...

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If the sourceSpeed is greater than the targetSpeed (magnitude of the targetVelocity), then there is always at least one solution. If the sourceSpeed is smaller or equal to the targetSpeed, there might or might not be any solutions. You can parametrize the path of the target by the amount of time that it takes for the target to get there, t. You want to ...

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The answer depends on the amount of time you want it to take to reach the target. Try these two formulas bullet distance = target distance + (target velocity * time) bullet velocity * time = target distance + (target velocity * time)​

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For integer exponents this is called Hermite interpolation. One can also interpret this task as an application of the chinese remainder theorem in polynomial rings f(x) == 0 mod x^p f(x) == 1 mod (x-1)^p The solution has the form f(x) = a(x)*x^p+b(x)*(x-1)^p with deg a(x) < p, deg b(x) < p. Inserting into the second equations gives ...

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Lets values = 1,2,3,4,5 the following will yield 5 project(a)values - project(a1)((select 'a1' < 'a2') ((rename 'a' as 'a1')(values) x (rename 'a' as 'a2')(values)))

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that is 6.280369834735099E-16 aka 6.280369834735099*10^-16 aka 0.000000000000000628 therefor its almost zero aka 0.00 MFG MiSt

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I found the solution to my own question: /* circle_circle_intersection() * * Determine the points where 2 circles in a common plane intersect. * * int circle_circle_intersection( * // center and radius of 1st circle * double x0, double y0, double r0, * // ...

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Just change around your equation so t is alone: var fp = .25; var acres = 40; var rt = 13; var v = 13.3; t = ((v - rt) * acres) / fp; console.log(t); // ~48

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