alexander-soare · April 4, 2026 00:29
diff --git a/epps_pulley_statistic.py b/epps_pulley_statistic.py
 import time

 import torch
 import matplotlib.pyplot as plt

 D = 2  # dimension
 N = 8  # number of projections
 B = 512  # batch size
 K = 17  # knots
 U = 3  # upper bound of fourier domain

 # Choose a starting distribution
 # X = torch.normal(0.0, 0.5, size=(B, D))
 X = torch.rand(size=(B, D)) * 2 - 1

 X = torch.nn.Parameter(X.clone())
 t = torch.linspace(0, U, K)
 dt = U / (K - 1)
 target = (-t.pow(2) / 2.0).exp()
 weights = torch.full((K,), 2 * dt) * target
 weights[[0, -1]] = dt

 step = 0


 def plot(t, X, re_fX, im_fX, target):
    fig = plt.figure(figsize=(12, 8))
    gs = fig.add_gridspec(D, 2, width_ratios=[0.8, 1.2], hspace=0.4, wspace=0.3)

    for i in range(D):
        ax = fig.add_subplot(gs[i, 0])
        ax.plot(t, re_fX[i], "o", label="real")
        ax.plot(t, im_fX[i], "o", label="imag")
        ax.plot(t, target, color="red", label="targ")
        ax.legend()

    # Scatter plot spanning all rows in the right column
    scatter_ax = fig.add_subplot(gs[:, 1], aspect="equal")
    scatter_ax.plot(X[:, 0], X[:, 1], ".")
    theta = torch.linspace(0, 2 * 3.14159265, 200)
    for r in [1, 2, 3]:
        scatter_ax.plot((r * theta.cos()).numpy(), (r * theta.sin()).numpy(), "r-", linewidth=1)
    scatter_ax.set_xlim(-U, U)
    scatter_ax.set_ylim(-U, U)
    scatter_ax.axhline(0, color="gray", linewidth=0.5)
    scatter_ax.axvline(0, color="gray", linewidth=0.5)
    scatter_ax.grid(True, linewidth=0.5, alpha=0.5)

    save_to = "outputs/epps_pulley_statistic.png"
    plt.savefig(save_to, dpi=150)
    plt.close()


 def project_fourier(random: bool = True) -> tuple[torch.Tensor, torch.Tensor]:
    if random:
        # Pick N random unit vectors.
        V = torch.normal(0, 1, (N, D))
        V = V / V.norm(p=2, dim=-1, keepdim=True)
    else:
        # Project onto the basis vectors.
        V = torch.eye(D)

    # Project X onto these vectors
    P = X @ V.T  # (B N)

    P_t = P[..., None] * t  # (B N t)

    # Real and imaginary parts of fourier transform
    # Mean over "batch" to get empirical characteristic function
    re_F = P_t.cos().mean(0)  # (N t)
    im_F = P_t.sin().mean(0)  # (N t)

    return re_F, im_F

 while True:
    re_F, im_F = project_fourier()

    err = (re_F - target).pow(2) + im_F.pow(2)
    statistic = B * err @ weights  # (N)
    loss = statistic.mean()

    loss.backward()

    # Plot for the basis vector projections.
    with torch.no_grad():
        basis_re_F, basis_im_F = project_fourier(random=False)
        plot(
            t.numpy(),
            X.detach().numpy(),
            basis_re_F.numpy(),
            basis_im_F.numpy(),
            target.numpy(),
        )
    print("STEP:", step)
    print(f"Mean: {X.mean().item()}, Std: {X.std().item()}")
    print("Loss:", loss.item())
    print("Grad magnitude:", X.grad.pow(2).sum().sqrt().item())

    # Gradient step
    X = torch.nn.Parameter(X.detach() - X.grad * 0.5)

    step += 1
    time.sleep(0.1)
	import time

	import torch
	import matplotlib.pyplot as plt

	D = 2 # dimension
	N = 8 # number of projections
	B = 512 # batch size
	K = 17 # knots
	U = 3 # upper bound of fourier domain

	# Choose a starting distribution
	# X = torch.normal(0.0, 0.5, size=(B, D))
	X = torch.rand(size=(B, D)) * 2 - 1

	X = torch.nn.Parameter(X.clone())
	t = torch.linspace(0, U, K)
	dt = U / (K - 1)
	target = (-t.pow(2) / 2.0).exp()
	weights = torch.full((K,), 2 * dt) * target
	weights[[0, -1]] = dt

	step = 0


	def plot(t, X, re_fX, im_fX, target):
	fig = plt.figure(figsize=(12, 8))
	gs = fig.add_gridspec(D, 2, width_ratios=[0.8, 1.2], hspace=0.4, wspace=0.3)

	for i in range(D):
	ax = fig.add_subplot(gs[i, 0])
	ax.plot(t, re_fX[i], "o", label="real")
	ax.plot(t, im_fX[i], "o", label="imag")
	ax.plot(t, target, color="red", label="targ")
	ax.legend()

	# Scatter plot spanning all rows in the right column
	scatter_ax = fig.add_subplot(gs[:, 1], aspect="equal")
	scatter_ax.plot(X[:, 0], X[:, 1], ".")
	theta = torch.linspace(0, 2 * 3.14159265, 200)
	for r in [1, 2, 3]:
	scatter_ax.plot((r * theta.cos()).numpy(), (r * theta.sin()).numpy(), "r-", linewidth=1)
	scatter_ax.set_xlim(-U, U)
	scatter_ax.set_ylim(-U, U)
	scatter_ax.axhline(0, color="gray", linewidth=0.5)
	scatter_ax.axvline(0, color="gray", linewidth=0.5)
	scatter_ax.grid(True, linewidth=0.5, alpha=0.5)

	save_to = "outputs/epps_pulley_statistic.png"
	plt.savefig(save_to, dpi=150)
	plt.close()


	def project_fourier(random: bool = True) -> tuple[torch.Tensor, torch.Tensor]:
	if random:
	# Pick N random unit vectors.
	V = torch.normal(0, 1, (N, D))
	V = V / V.norm(p=2, dim=-1, keepdim=True)
	else:
	# Project onto the basis vectors.
	V = torch.eye(D)

	# Project X onto these vectors
	P = X @ V.T # (B N)

	P_t = P[..., None] * t # (B N t)

	# Real and imaginary parts of fourier transform
	# Mean over "batch" to get empirical characteristic function
	re_F = P_t.cos().mean(0) # (N t)
	im_F = P_t.sin().mean(0) # (N t)

	return re_F, im_F

	while True:
	re_F, im_F = project_fourier()

	err = (re_F - target).pow(2) + im_F.pow(2)
	statistic = B * err @ weights # (N)
	loss = statistic.mean()

	loss.backward()

	# Plot for the basis vector projections.
	with torch.no_grad():
	basis_re_F, basis_im_F = project_fourier(random=False)
	plot(
	t.numpy(),
	X.detach().numpy(),
	basis_re_F.numpy(),
	basis_im_F.numpy(),
	target.numpy(),
	)
	print("STEP:", step)
	print(f"Mean: {X.mean().item()}, Std: {X.std().item()}")
	print("Loss:", loss.item())
	print("Grad magnitude:", X.grad.pow(2).sum().sqrt().item())

	# Gradient step
	X = torch.nn.Parameter(X.detach() - X.grad * 0.5)

	step += 1
	time.sleep(0.1)
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