Thus the Pólya field rotates the usual representation of (f) by reflecting across the real axis. Write (f(z) = u + i v). Then:
We want (\mathbfV_f = (u, -v) = (\partial \psi / \partial y,; -\partial \psi / \partial x)). From the first component: (\partial \psi / \partial y = u). From the second: (-\partial \psi / \partial x = -v \Rightarrow \partial \psi / \partial x = v). polya vector field
Indeed, the stream function (\psi) such that (\mathbfV_f = ( \psi_y, -\psi_x )) can be taken as (\psi = -v). Check: [ \psi_y = -v_y = -(-u_x) = u_x? \text Wait carefully. ] Better: Let (\psi = -v). Then (\nabla^\perp \psi = (\psi_y, -\psi_x) = (-v_y, v_x)). But by Cauchy–Riemann, (v_x = u_y), (v_y = -u_x), so ((-v_y, v_x) = (u_x, u_y)) — that’s (\nabla u), not (\mathbfV_f). So that’s not correct. Let's derive cleanly: Thus the Pólya field rotates the usual representation
Equivalently, if (f = u+iv), then (\mathbfV_f = (u, -v)). The Pólya vector field is the conjugate of the complex velocity field (\overlinef(z)). Indeed, (\overlinef(z) = u - i v), which as a vector in (\mathbbR^2) is ((u, -v)). From the first component: (\partial \psi / \partial y = u)
Let (\phi = u) (potential). Then
Thus the Pólya field rotates the usual representation of (f) by reflecting across the real axis. Write (f(z) = u + i v). Then:
We want (\mathbfV_f = (u, -v) = (\partial \psi / \partial y,; -\partial \psi / \partial x)). From the first component: (\partial \psi / \partial y = u). From the second: (-\partial \psi / \partial x = -v \Rightarrow \partial \psi / \partial x = v).
Indeed, the stream function (\psi) such that (\mathbfV_f = ( \psi_y, -\psi_x )) can be taken as (\psi = -v). Check: [ \psi_y = -v_y = -(-u_x) = u_x? \text Wait carefully. ] Better: Let (\psi = -v). Then (\nabla^\perp \psi = (\psi_y, -\psi_x) = (-v_y, v_x)). But by Cauchy–Riemann, (v_x = u_y), (v_y = -u_x), so ((-v_y, v_x) = (u_x, u_y)) — that’s (\nabla u), not (\mathbfV_f). So that’s not correct. Let's derive cleanly:
Equivalently, if (f = u+iv), then (\mathbfV_f = (u, -v)). The Pólya vector field is the conjugate of the complex velocity field (\overlinef(z)). Indeed, (\overlinef(z) = u - i v), which as a vector in (\mathbbR^2) is ((u, -v)).
Let (\phi = u) (potential). Then
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