
# Set working directory
import os
os.chdir("..")

# Handling arrays and data.frames
import pandas as pd 
import numpy as np

# Loading R objects into python
import rpy2.robjects as ro
from rpy2.robjects import pandas2ri 

# Pytorch compatible topology layer and losses
import torch
from topologylayer.nn import AlphaLayer
from Code.losses import DiagramLoss, umap_loss

# Ordinary and topologically regularized UMAP embedding
from Code.topembed import UMAP
UMAP(np.array(np.random.rand(30, 5)), num_epochs=0) # Execute once for numba code compilation

# Plotting
import seaborn as sns
import matplotlib.pyplot as plt

# Quantitative evaluation
from sklearn.svm import SVC
from Code.evaluation import evaluate_embeddings

%matplotlib inline


# Load the data
file_name = os.path.join("Data", "CellBifurcating.rds")
cell_info = ro.r["readRDS"](file_name)
cell_info = dict(zip(cell_info.names, list(cell_info)))

pandas2ri.activate()
data = ro.conversion.rpy2py(cell_info["expression"])
t = list(ro.conversion.rpy2py(cell_info["cell_info"])
         .rename(columns={"milestone_id": "group_id"}).loc[:,"group_id"])
pandas2ri.deactivate()

print("Data shape: " + str(data.shape))

# Learning hyperparameters
num_epochs = 100
learning_rate = 1e-1

# Conduct ordinary UMAP embedding
Y_umap, losses_umap = UMAP(data, num_epochs=num_epochs, learning_rate=learning_rate, random_state=42)

# View the data through its UMAP embedding
fig, ax = plt.subplots()
sns.scatterplot(x=Y_umap[:,0], y=Y_umap[:,1], s=50, hue=t, palette="husl")
ax.get_legend().remove()
plt.show()

Data shape: (154, 1770)
[epoch 1] [emb. loss: 9376.855727, top. loss: 0.000000, total loss: 9376.855727]
[epoch 10] [emb. loss: 9103.008830, top. loss: 0.000000, total loss: 9103.008830]
[epoch 20] [emb. loss: 8850.547525, top. loss: 0.000000, total loss: 8850.547525]
[epoch 30] [emb. loss: 8824.020165, top. loss: 0.000000, total loss: 8824.020165]
[epoch 40] [emb. loss: 8703.961411, top. loss: 0.000000, total loss: 8703.961411]
[epoch 50] [emb. loss: 8450.941803, top. loss: 0.000000, total loss: 8450.941803]
[epoch 60] [emb. loss: 8749.852056, top. loss: 0.000000, total loss: 8749.852056]
[epoch 70] [emb. loss: 8618.780763, top. loss: 0.000000, total loss: 8618.780763]
[epoch 80] [emb. loss: 8421.186200, top. loss: 0.000000, total loss: 8421.186200]
[epoch 90] [emb. loss: 8466.879089, top. loss: 0.000000, total loss: 8466.879089]
[epoch 100] [emb. loss: 8419.206423, top. loss: 0.000000, total loss: 8419.206423]
Time for embedding: 00:00:00


# Define topological optimization
def g(p): return p[1] - p[0] # function that returns the persistence d - b of a point (b, d)
TopLayer = AlphaLayer(maxdim=1) # alpha complex layer
ComponentPersistence = DiagramLoss(dim=0, i=2, g=g) # compute total (finite) persistence
Component3Persistence = DiagramLoss(dim=0, i=3, j=3, g=g) # compute persistence of third most prominent gap
lambda_top = 1e1 # scalar factor that trades off embedding and topological loss
tau_flare = 0.25 # sample fraction for which the flare topological loss is computed

# Construct topological loss function
def top_loss(output):    
    # Loss for connectedness
    dgminfo_connected = TopLayer(output)         
    loss_connected = ComponentPersistence(dgminfo_connected)

    # Loss for flare
    f = torch.norm(output - torch.mean(output, dim=0), dim=1)
    f /= torch.max(f)
    dgminfo_flare = TopLayer(output[f > tau_flare,:])
    loss_flare = -Component3Persistence(dgminfo_flare)    
        
    # Total loss
    loss = lambda_top * (loss_connected + loss_flare)
    
    return loss


# Learning hyperparameters
num_epochs = 100
learning_rate = 1e-1

# Conduct topological regularization
Y_top, losses_top = UMAP(data, top_loss=top_loss, num_epochs=num_epochs, 
                         learning_rate=learning_rate, random_state=42)

# View topologically regularized embedding
fig, ax = plt.subplots()
sns.scatterplot(x=Y_top[:,0], y=Y_top[:,1], s=50, hue=t, palette="husl")
ax.get_legend().remove()
plt.show()

[epoch 1] [emb. loss: 9376.855727, top. loss: 1412.720459, total loss: 10789.576186]
[epoch 10] [emb. loss: 9424.549514, top. loss: 967.172241, total loss: 10391.721755]
[epoch 20] [emb. loss: 9237.509794, top. loss: 804.668701, total loss: 10042.178495]
[epoch 30] [emb. loss: 9163.613059, top. loss: 710.923767, total loss: 9874.536827]
[epoch 40] [emb. loss: 9133.507288, top. loss: 658.947815, total loss: 9792.455103]
[epoch 50] [emb. loss: 9239.509584, top. loss: 652.785522, total loss: 9892.295106]
[epoch 60] [emb. loss: 9136.785422, top. loss: 643.777466, total loss: 9780.562888]
[epoch 70] [emb. loss: 9038.252752, top. loss: 629.470581, total loss: 9667.723333]
[epoch 80] [emb. loss: 8974.596282, top. loss: 643.432922, total loss: 9618.029205]
[epoch 90] [emb. loss: 9085.446099, top. loss: 623.973328, total loss: 9709.419426]
[epoch 100] [emb. loss: 8981.926104, top. loss: 630.493286, total loss: 9612.419390]
Time for embedding: 00:00:07


# Learning hyperparameters
num_epochs = 100
learning_rate = 1e-1

# Conduct topological optimization (UMAP)
Y_opt, losses_opt = UMAP(Y_umap, emb_loss=False, top_loss=top_loss, num_epochs=num_epochs, 
                         learning_rate=learning_rate, random_state=42)

# View topologically optimized embedding (UMAP)
fig, ax = plt.subplots()
sns.scatterplot(x=Y_opt[:,0], y=Y_opt[:,1], s=50, hue=t, palette="husl")
ax.get_legend().remove()
plt.show()

[epoch 1] [emb. loss: 0.000000, top. loss: 1167.495728, total loss: 1167.495728]
[epoch 10] [emb. loss: 0.000000, top. loss: 723.169067, total loss: 723.169067]
[epoch 20] [emb. loss: 0.000000, top. loss: 539.727295, total loss: 539.727295]
[epoch 30] [emb. loss: 0.000000, top. loss: 429.159058, total loss: 429.159058]
[epoch 40] [emb. loss: 0.000000, top. loss: 364.528503, total loss: 364.528503]
[epoch 50] [emb. loss: 0.000000, top. loss: 320.426392, total loss: 320.426392]
[epoch 60] [emb. loss: 0.000000, top. loss: 288.649963, total loss: 288.649963]
[epoch 70] [emb. loss: 0.000000, top. loss: 267.297821, total loss: 267.297821]
[epoch 80] [emb. loss: 0.000000, top. loss: 252.922058, total loss: 252.922058]
[epoch 90] [emb. loss: 0.000000, top. loss: 242.767914, total loss: 242.767914]
[epoch 100] [emb. loss: 0.000000, top. loss: 233.778214, total loss: 233.778214]
Time for embedding: 00:00:09


print("\033[1mLosses for umap embedding: \033[0m")
print("Embedding: " + str(umap_loss(losses_umap["P"], torch.tensor(Y_umap).type(torch.float), 
                                    losses_umap["a"], losses_umap["b"]).item()))
print("Topological: " + str(top_loss(torch.tensor(Y_umap).type(torch.float)).item() / np.abs(lambda_top)) + "\n")

print("\033[1mLosses for topologically optimized umap embedding: \033[0m")
print("Embedding: " + str(umap_loss(losses_opt["P"], torch.tensor(Y_opt).type(torch.float), 
                                    losses_opt["a"], losses_opt["b"]).item()))
print("Topological: " + str(top_loss(torch.tensor(Y_opt).type(torch.float)).item() / 
                            np.abs(lambda_top)) + "\n")

print("\033[1mLosses for topologically regularized umap embedding: \033[0m")
print("Embedding: " + str(umap_loss(losses_top["P"], torch.tensor(Y_top).type(torch.float), 
                                    losses_top["a"], losses_top["b"]).item()))
print("Topological: " + str(top_loss(torch.tensor(Y_top).type(torch.float)).item() / np.abs(lambda_top)))

Losses for umap embedding: 
Embedding: 8576.364944816134
Topological: 116.74957275390625

Losses for topologically optimized umap embedding: 
Embedding: 9932.898996191445
Topological: 23.302349853515626

Losses for topologically regularized umap embedding: 
Embedding: 8871.473401997777
Topological: 62.9324462890625


# Machine learning model to be used for label prediction
Ys = {"umap": Y_umap, "top. opt.": Y_opt, "top. reg.": Y_top}
model = SVC()
scoring = "accuracy"

# Hyperparameters for quantitative evaluation
ntimes = 100
test_frac = 0.1
params = {"C":[0.01, 0.1, 1, 10, 100]}

# Obtain performances over multiple train-test splits
performances = evaluate_embeddings(Ys, t, model, scoring, params=params, stratify=t,
                                   ntimes=ntimes, test_frac=test_frac, random_state=42)

# View resulting performances
pd.concat([pd.DataFrame({"mean":performances.mean(axis=0)}),
           pd.DataFrame({"std":performances.std(axis=0)})], axis=1)\
            .style.highlight_max(subset="mean", color="lightgreen", axis=0)


# Learning hyperparameters
num_epochs = 100
learning_rate = 1e-1

# Conduct topological regularization for flare thresholds tau
taus = [0.75, 0.5, 0.25] # note that tau (main paper) = 1 - tau (notebook)
Y_taus = []

for idx, tau in enumerate(taus):
    # Construct topological loss function
    def tau_top_loss(output):    
        # Loss for connectedness
        dgminfo_connected = TopLayer(output)         
        loss_connected = ComponentPersistence(dgminfo_connected)

        # Loss for flare
        f = torch.norm(output - torch.mean(output, dim=0), dim=1)
        f /= torch.max(f)
        dgminfo_flare = TopLayer(output[f > tau,:])
        loss_flare = -Component3Persistence(dgminfo_flare)

        # Total loss
        loss = lambda_top * (loss_connected + loss_flare)

        return loss

    # Conduct topological regularization
    print("\033[1mConducting topologically regularized embedding for tau = " + str(1 - tau) + "\033[0m")
    this_Y_tau, losses_tau = UMAP(data, top_loss=tau_top_loss, num_epochs=num_epochs, 
                                  learning_rate=learning_rate, random_state=42)
    Y_taus.append(this_Y_tau)
    print("\n")
    
# View topologically regularized embeddings for different thresholds tau
fig, ax = plt.subplots(1, 3, figsize=(15, 3.5))
for idx, tau in enumerate(taus):
    sns.scatterplot(x=Y_taus[idx][:,0], y=Y_taus[idx][:,1], s=50, hue=t, palette="husl", ax=ax[idx])
    ax[idx].get_legend().remove()
    ax[idx].set_title(r"$\tau$ = " + str(1 - tau))
plt.show()

Conducting topologically regularized embedding for tau = 0.25
[epoch 1] [emb. loss: 9376.855727, top. loss: 1458.245239, total loss: 10835.100966]
[epoch 10] [emb. loss: 9415.376703, top. loss: 1013.097839, total loss: 10428.474542]
[epoch 20] [emb. loss: 9367.941448, top. loss: 872.273071, total loss: 10240.214519]
[epoch 30] [emb. loss: 9285.828090, top. loss: 775.673889, total loss: 10061.501979]
[epoch 40] [emb. loss: 9281.692348, top. loss: 737.991821, total loss: 10019.684169]
[epoch 50] [emb. loss: 9125.022434, top. loss: 728.142822, total loss: 9853.165257]
[epoch 60] [emb. loss: 9189.738371, top. loss: 721.931274, total loss: 9911.669646]
[epoch 70] [emb. loss: 9032.871499, top. loss: 710.517517, total loss: 9743.389016]
[epoch 80] [emb. loss: 8947.278904, top. loss: 697.761475, total loss: 9645.040379]
[epoch 90] [emb. loss: 9027.731164, top. loss: 686.090942, total loss: 9713.822106]
[epoch 100] [emb. loss: 8917.668728, top. loss: 682.858276, total loss: 9600.527004]
Time for embedding: 00:00:04


Conducting topologically regularized embedding for tau = 0.5
[epoch 1] [emb. loss: 9376.855727, top. loss: 1366.098755, total loss: 10742.954482]
[epoch 10] [emb. loss: 9180.298697, top. loss: 914.549255, total loss: 10094.847952]
[epoch 20] [emb. loss: 9265.636038, top. loss: 736.941467, total loss: 10002.577505]
[epoch 30] [emb. loss: 9180.415900, top. loss: 632.937561, total loss: 9813.353461]
[epoch 40] [emb. loss: 9252.427713, top. loss: 599.358093, total loss: 9851.785806]
[epoch 50] [emb. loss: 9105.864087, top. loss: 587.109436, total loss: 9692.973523]
[epoch 60] [emb. loss: 9207.009473, top. loss: 579.573669, total loss: 9786.583142]
[epoch 70] [emb. loss: 9173.441741, top. loss: 573.375793, total loss: 9746.817535]
[epoch 80] [emb. loss: 8865.755123, top. loss: 574.220093, total loss: 9439.975216]
[epoch 90] [emb. loss: 9053.634942, top. loss: 579.570435, total loss: 9633.205377]
[epoch 100] [emb. loss: 9162.937852, top. loss: 582.826111, total loss: 9745.763963]
Time for embedding: 00:00:05


Conducting topologically regularized embedding for tau = 0.75
[epoch 1] [emb. loss: 9376.855727, top. loss: 1412.720459, total loss: 10789.576186]
[epoch 10] [emb. loss: 9424.549514, top. loss: 967.172241, total loss: 10391.721755]
[epoch 20] [emb. loss: 9237.509794, top. loss: 804.668701, total loss: 10042.178495]
[epoch 30] [emb. loss: 9163.613059, top. loss: 710.923767, total loss: 9874.536827]
[epoch 40] [emb. loss: 9133.507288, top. loss: 658.947815, total loss: 9792.455103]
[epoch 50] [emb. loss: 9239.509584, top. loss: 652.785522, total loss: 9892.295106]
[epoch 60] [emb. loss: 9136.785422, top. loss: 643.777466, total loss: 9780.562888]
[epoch 70] [emb. loss: 9038.252752, top. loss: 629.470581, total loss: 9667.723333]
[epoch 80] [emb. loss: 8974.596282, top. loss: 643.432922, total loss: 9618.029205]
[epoch 90] [emb. loss: 9085.446099, top. loss: 623.973328, total loss: 9709.419426]
[epoch 100] [emb. loss: 8981.926104, top. loss: 630.493286, total loss: 9612.419390]
Time for embedding: 00:00:06


# Learning hyperparameters
num_epochs = 100
learning_rate = 1e-1

# Conduct topological regularization for different powers of the persistence lifetime
powers = [1 / 2, 1, 2] # p = 1 equals or previous case, which we include for easy comparison
Y_tops = []

for idx, p in enumerate(powers):
    # Construct topological loss function
    def gp(d): return (d[1] - d[0])**p # returns the p-th power of the persistence d - b of a point (b, d)
    pComponentPersistence = DiagramLoss(dim=0, i=2, g=gp) # for low total (finite) persistence
    pComponent3Persistence = DiagramLoss(dim=0, i=3, j=3, g=gp) # for high persistence of third most prominent gap
    def p_top_loss(output):    
        # Loss for connectedness
        dgminfo_connected = TopLayer(output)         
        loss_connected = pComponentPersistence(dgminfo_connected)

        # Loss for flare
        f = torch.norm(output - torch.mean(output, dim=0), dim=1)
        f /= torch.max(f)
        dgminfo_flare = TopLayer(output[f > tau_flare,:])
        loss_flare = -pComponent3Persistence(dgminfo_flare)

        # Total loss
        loss = lambda_top * (loss_connected + loss_flare)

        return loss

    # Conduct topological regularization
    print("\033[1mConducting topologically regularized embedding for lifetime power " + str(p) + "\033[0m")
    this_Y_top, losses_top = UMAP(data, top_loss=p_top_loss, num_epochs=num_epochs, 
                                  learning_rate=learning_rate, random_state=42)
    Y_tops.append(this_Y_top)
    print("\n")
    
# View topologically regularized embeddings for different persistence lifetime powers
fig, ax = plt.subplots(1, 3, figsize=(15, 3.5))
for idx, p in enumerate(powers):
    sns.scatterplot(x=Y_tops[idx][:,0], y=Y_tops[idx][:,1], s=50, hue=t, palette="husl", ax=ax[idx])
    ax[idx].get_legend().remove()
    ax[idx].set_title("p = " + str(p))
plt.show()

Conducting topologically regularized embedding for lifetime power 0.5
[epoch 1] [emb. loss: 9376.855727, top. loss: 1400.352173, total loss: 10777.207900]
[epoch 10] [emb. loss: 9150.710593, top. loss: 1202.514771, total loss: 10353.225364]
[epoch 20] [emb. loss: 9151.445905, top. loss: 1126.345215, total loss: 10277.791120]
[epoch 30] [emb. loss: 9055.769724, top. loss: 1076.250000, total loss: 10132.019724]
[epoch 40] [emb. loss: 8940.097309, top. loss: 1046.674316, total loss: 9986.771625]
[epoch 50] [emb. loss: 8987.077069, top. loss: 1028.369385, total loss: 10015.446454]
[epoch 60] [emb. loss: 8903.144402, top. loss: 1028.905396, total loss: 9932.049798]
[epoch 70] [emb. loss: 8937.635326, top. loss: 1003.204895, total loss: 9940.840221]
[epoch 80] [emb. loss: 8786.045473, top. loss: 1004.524902, total loss: 9790.570375]
[epoch 90] [emb. loss: 8853.924331, top. loss: 984.087219, total loss: 9838.011550]
[epoch 100] [emb. loss: 8987.524060, top. loss: 987.737366, total loss: 9975.261426]
Time for embedding: 00:00:07


Conducting topologically regularized embedding for lifetime power 1
[epoch 1] [emb. loss: 9376.855727, top. loss: 1412.720459, total loss: 10789.576186]
[epoch 10] [emb. loss: 9424.549514, top. loss: 967.172241, total loss: 10391.721755]
[epoch 20] [emb. loss: 9237.509794, top. loss: 804.668701, total loss: 10042.178495]
[epoch 30] [emb. loss: 9163.613059, top. loss: 710.923767, total loss: 9874.536827]
[epoch 40] [emb. loss: 9133.507288, top. loss: 658.947815, total loss: 9792.455103]
[epoch 50] [emb. loss: 9239.509584, top. loss: 652.785522, total loss: 9892.295106]
[epoch 60] [emb. loss: 9136.785422, top. loss: 643.777466, total loss: 9780.562888]
[epoch 70] [emb. loss: 9038.252752, top. loss: 629.470581, total loss: 9667.723333]
[epoch 80] [emb. loss: 8974.596282, top. loss: 643.432922, total loss: 9618.029205]
[epoch 90] [emb. loss: 9085.446099, top. loss: 623.973328, total loss: 9709.419426]
[epoch 100] [emb. loss: 8981.926104, top. loss: 630.493286, total loss: 9612.419390]
Time for embedding: 00:00:07


Conducting topologically regularized embedding for lifetime power 2
[epoch 1] [emb. loss: 9376.855727, top. loss: 1620.952148, total loss: 10997.807875]
[epoch 10] [emb. loss: 9415.493040, top. loss: 460.171783, total loss: 9875.664824]
[epoch 20] [emb. loss: 9242.411157, top. loss: 153.157578, total loss: 9395.568734]
[epoch 30] [emb. loss: 9168.856423, top. loss: -5.797577, total loss: 9163.058846]
[epoch 40] [emb. loss: 9254.240796, top. loss: -21.707993, total loss: 9232.532803]
[epoch 50] [emb. loss: 9219.296454, top. loss: -116.257019, total loss: 9103.039435]
[epoch 60] [emb. loss: 9142.757277, top. loss: -162.312286, total loss: 8980.444990]
[epoch 70] [emb. loss: 9267.836763, top. loss: -182.079132, total loss: 9085.757631]
[epoch 80] [emb. loss: 9196.095215, top. loss: -146.404800, total loss: 9049.690415]
[epoch 90] [emb. loss: 9374.382597, top. loss: -141.650543, total loss: 9232.732054]
[epoch 100] [emb. loss: 9039.833428, top. loss: -109.867249, total loss: 8929.966180]
Time for embedding: 00:00:07


# Define different topological loss
def g(p): return p[1] - p[0] # function that returns the persistence d - b of a point (b, d)
TopLayer = AlphaLayer(maxdim=1) # alpha complex layer
CircularPersistence = DiagramLoss(dim=1, j=1, g=g) # compute persistence of most prominent cycle
lambda_top = 1e1 # scalar factor that trades off embedding and topological loss

# Construct the topological loss functions
def top_loss_other(output):
    dgminfo = TopLayer(output)
    loss = -lambda_top * (CircularPersistence(dgminfo))
    
    return loss


# Learning hyperparameters
num_epochs = [100, 250, 1000]
learning_rate = 1e-1

# Conduct topological regularization for multiple number of epochs
Y_epochs = {}
for epochs in num_epochs:
    print("\033[1mConducting topologically regularized embedding for " + str(epochs) + " epochs\033[0m")
    Y_epochs[epochs], losses_top_other = UMAP(data, top_loss=top_loss_other, num_epochs=epochs, 
                                              learning_rate=learning_rate, random_state=42)
    print("\n")
    
# View topologically regularized embeddings
fig, ax = plt.subplots(1, len(num_epochs), figsize=(len(num_epochs) * 5, 3.5))
for idx, epochs in enumerate(num_epochs):
    sns.scatterplot(x=Y_epochs[epochs][:,0], y=Y_epochs[epochs][:,1], s=50, hue=t, palette="husl", ax=ax[idx])
    ax[idx].get_legend().remove()
    ax[idx].set_title(str(epochs) + " epochs (with UMAP loss)")
plt.show()

Conducting topologically regularized embedding for 100 epochs
[epoch 1] [emb. loss: 9376.855727, top. loss: -15.400949, total loss: 9361.454778]
[epoch 10] [emb. loss: 9039.074319, top. loss: -26.457535, total loss: 9012.616785]
[epoch 20] [emb. loss: 8869.637188, top. loss: -33.650097, total loss: 8835.987091]
[epoch 30] [emb. loss: 8756.361980, top. loss: -37.516628, total loss: 8718.845352]
[epoch 40] [emb. loss: 8618.454895, top. loss: -39.182213, total loss: 8579.272682]
[epoch 50] [emb. loss: 8743.236561, top. loss: -44.038883, total loss: 8699.197678]
[epoch 60] [emb. loss: 8721.251276, top. loss: -38.449944, total loss: 8682.801333]
[epoch 70] [emb. loss: 8716.132112, top. loss: -43.078751, total loss: 8673.053362]
[epoch 80] [emb. loss: 8541.475153, top. loss: -41.121223, total loss: 8500.353930]
[epoch 90] [emb. loss: 8631.374361, top. loss: -40.123985, total loss: 8591.250375]
[epoch 100] [emb. loss: 8543.023783, top. loss: -37.061806, total loss: 8505.961977]
Time for embedding: 00:00:03


Conducting topologically regularized embedding for 250 epochs
[epoch 1] [emb. loss: 9376.855727, top. loss: -15.400949, total loss: 9361.454778]
[epoch 25] [emb. loss: 8742.524909, top. loss: -37.192924, total loss: 8705.331984]
[epoch 50] [emb. loss: 8743.236561, top. loss: -44.038883, total loss: 8699.197678]
[epoch 75] [emb. loss: 8599.089407, top. loss: -42.880722, total loss: 8556.208685]
[epoch 100] [emb. loss: 8543.023783, top. loss: -37.061806, total loss: 8505.961977]
[epoch 125] [emb. loss: 8472.216253, top. loss: -41.600071, total loss: 8430.616182]
[epoch 150] [emb. loss: 8426.644576, top. loss: -42.705544, total loss: 8383.939032]
[epoch 175] [emb. loss: 8596.689063, top. loss: -45.832348, total loss: 8550.856715]
[epoch 200] [emb. loss: 8512.560573, top. loss: -47.835533, total loss: 8464.725040]
[epoch 225] [emb. loss: 8489.846744, top. loss: -47.965004, total loss: 8441.881740]
[epoch 250] [emb. loss: 8378.663044, top. loss: -51.647968, total loss: 8327.015076]
Time for embedding: 00:00:09


Conducting topologically regularized embedding for 1000 epochs
[epoch 1] [emb. loss: 9376.855727, top. loss: -15.400949, total loss: 9361.454778]
[epoch 100] [emb. loss: 8543.023783, top. loss: -37.061806, total loss: 8505.961977]
[epoch 200] [emb. loss: 8512.560573, top. loss: -47.835533, total loss: 8464.725040]
[epoch 300] [emb. loss: 8365.334773, top. loss: -51.214813, total loss: 8314.119960]
[epoch 400] [emb. loss: 8355.265528, top. loss: -40.292225, total loss: 8314.973303]
[epoch 500] [emb. loss: 8446.866949, top. loss: -40.418922, total loss: 8406.448026]
[epoch 600] [emb. loss: 8570.864994, top. loss: -40.061611, total loss: 8530.803382]
[epoch 700] [emb. loss: 8522.397476, top. loss: -37.163643, total loss: 8485.233833]
[epoch 800] [emb. loss: 8517.306434, top. loss: -39.136063, total loss: 8478.170371]
[epoch 900] [emb. loss: 8544.170196, top. loss: -37.374268, total loss: 8506.795928]
[epoch 1000] [emb. loss: 8543.322056, top. loss: -37.489784, total loss: 8505.832272]
Time for embedding: 00:00:34


# Learning hyperparameters
num_epochs = [100, 250, 1000]
learning_rate = 1e-1

# Conduct topological optimization for multiple number of epochs
Y_opt_epochs = {}
for epochs in num_epochs:
    print("\033[1mConducting topologically optimization for " + str(epochs) + " epochs\033[0m")
    Y_opt_epochs[epochs], losses_opt_other = UMAP(Y_umap, emb_loss=False, top_loss=top_loss_other, 
                                                  num_epochs=epochs, learning_rate=learning_rate, random_state=42)
    print("\n")
    
# View topologically optimized embeddings
fig, ax = plt.subplots(1, len(num_epochs), figsize=(len(num_epochs) * 5, 3.5))
for idx, epochs in enumerate(num_epochs):
    sns.scatterplot(x=Y_opt_epochs[epochs][:,0], y=Y_opt_epochs[epochs][:,1], 
                    s=50, hue=t, palette="husl", ax=ax[idx])
    ax[idx].get_legend().remove()
    ax[idx].set_title(str(epochs) + " epochs (without UMAP loss)")
plt.show()

Conducting topologically optimization for 100 epochs
[epoch 1] [emb. loss: 0.000000, top. loss: -8.952889, total loss: -8.952889]
[epoch 10] [emb. loss: 0.000000, top. loss: -29.148804, total loss: -29.148804]
[epoch 20] [emb. loss: 0.000000, top. loss: -36.754570, total loss: -36.754570]
[epoch 30] [emb. loss: 0.000000, top. loss: -47.674465, total loss: -47.674465]
[epoch 40] [emb. loss: 0.000000, top. loss: -55.700363, total loss: -55.700363]
[epoch 50] [emb. loss: 0.000000, top. loss: -63.632767, total loss: -63.632767]
[epoch 60] [emb. loss: 0.000000, top. loss: -72.809006, total loss: -72.809006]
[epoch 70] [emb. loss: 0.000000, top. loss: -78.857086, total loss: -78.857086]
[epoch 80] [emb. loss: 0.000000, top. loss: -83.158836, total loss: -83.158836]
[epoch 90] [emb. loss: 0.000000, top. loss: -88.401649, total loss: -88.401649]
[epoch 100] [emb. loss: 0.000000, top. loss: -91.513374, total loss: -91.513374]
Time for embedding: 00:00:03


Conducting topologically optimization for 250 epochs
[epoch 1] [emb. loss: 0.000000, top. loss: -8.952889, total loss: -8.952889]
[epoch 25] [emb. loss: 0.000000, top. loss: -42.277710, total loss: -42.277710]
[epoch 50] [emb. loss: 0.000000, top. loss: -63.632767, total loss: -63.632767]
[epoch 75] [emb. loss: 0.000000, top. loss: -79.726387, total loss: -79.726387]
[epoch 100] [emb. loss: 0.000000, top. loss: -91.513374, total loss: -91.513374]
[epoch 125] [emb. loss: 0.000000, top. loss: -97.180016, total loss: -97.180016]
[epoch 150] [emb. loss: 0.000000, top. loss: -110.392914, total loss: -110.392914]
[epoch 175] [emb. loss: 0.000000, top. loss: -116.347336, total loss: -116.347336]
[epoch 200] [emb. loss: 0.000000, top. loss: -128.504272, total loss: -128.504272]
[epoch 225] [emb. loss: 0.000000, top. loss: -129.867584, total loss: -129.867584]
[epoch 250] [emb. loss: 0.000000, top. loss: -142.175247, total loss: -142.175247]
Time for embedding: 00:00:08


Conducting topologically optimization for 1000 epochs
[epoch 1] [emb. loss: 0.000000, top. loss: -8.952889, total loss: -8.952889]
[epoch 100] [emb. loss: 0.000000, top. loss: -91.513374, total loss: -91.513374]
[epoch 200] [emb. loss: 0.000000, top. loss: -128.504272, total loss: -128.504272]
[epoch 300] [emb. loss: 0.000000, top. loss: -156.839783, total loss: -156.839783]
[epoch 400] [emb. loss: 0.000000, top. loss: -183.337234, total loss: -183.337234]
[epoch 500] [emb. loss: 0.000000, top. loss: -210.123260, total loss: -210.123260]
[epoch 600] [emb. loss: 0.000000, top. loss: -238.513275, total loss: -238.513275]
[epoch 700] [emb. loss: 0.000000, top. loss: -263.181915, total loss: -263.181915]
[epoch 800] [emb. loss: 0.000000, top. loss: -289.233246, total loss: -289.233246]
[epoch 900] [emb. loss: 0.000000, top. loss: -314.791534, total loss: -314.791534]
[epoch 1000] [emb. loss: 0.000000, top. loss: -318.556366, total loss: -318.556366]
Time for embedding: 00:00:32


# Topological loss function with stronger regularization
lambda_top_multipliers = [1 / 10, 1, 10]

# Learning hyperparameters
num_epochs = 1000
learning_rate = 1e-1

# Conduct topological regularization for different topological loss function
Y_lambdas = {}
losses_lambdas = {}
for m in lambda_top_multipliers:
    def new_lambda_top_loss(output): return m * top_loss_other(output)
    print("\033[1mConducting topologically regularized embedding for lambda_top = " + 
          str(m * lambda_top) + "\033[0m")
    Y_lambdas[m], losses_lambdas[m] = UMAP(data, top_loss=new_lambda_top_loss, num_epochs=num_epochs, 
                                           learning_rate=learning_rate, random_state=42)
    print("\n")
    
# View topologically regularized embeddings
fig, ax = plt.subplots(1, len(lambda_top_multipliers), figsize=(len(lambda_top_multipliers) * 5, 3.5))
for idx, m in enumerate(lambda_top_multipliers):
    sns.scatterplot(x=Y_lambdas[m][:,0], y=Y_lambdas[m][:,1], s=50, hue=t, palette="husl", ax=ax[idx])
    ax[idx].get_legend().remove()
    ax[idx].set_title("$\lambda_{{{}}}$ = {} \n {} epochs (with UMAP loss)".
                      format("top",  m * lambda_top, num_epochs))
plt.show()

Conducting topologically regularized embedding for lambda_top = 1.0
[epoch 1] [emb. loss: 9376.855727, top. loss: -1.540095, total loss: 9375.315632]
[epoch 100] [emb. loss: 8381.159537, top. loss: -2.912832, total loss: 8378.246706]
[epoch 200] [emb. loss: 8490.889921, top. loss: -2.164753, total loss: 8488.725168]
[epoch 300] [emb. loss: 8457.992684, top. loss: -2.143497, total loss: 8455.849187]
[epoch 400] [emb. loss: 8397.265691, top. loss: -3.013646, total loss: 8394.252045]
[epoch 500] [emb. loss: 8442.959480, top. loss: -2.163042, total loss: 8440.796438]
[epoch 600] [emb. loss: 8631.406087, top. loss: -2.433714, total loss: 8628.972373]
[epoch 700] [emb. loss: 8472.105310, top. loss: -2.030765, total loss: 8470.074545]
[epoch 800] [emb. loss: 8449.583733, top. loss: -1.350383, total loss: 8448.233349]
[epoch 900] [emb. loss: 8438.075491, top. loss: -1.218628, total loss: 8436.856862]
[epoch 1000] [emb. loss: 8342.530128, top. loss: -1.157551, total loss: 8341.372577]
Time for embedding: 00:00:34


Conducting topologically regularized embedding for lambda_top = 10.0
[epoch 1] [emb. loss: 9376.855727, top. loss: -15.400949, total loss: 9361.454778]
[epoch 100] [emb. loss: 8543.023783, top. loss: -37.061806, total loss: 8505.961977]
[epoch 200] [emb. loss: 8512.560573, top. loss: -47.835533, total loss: 8464.725040]
[epoch 300] [emb. loss: 8365.334773, top. loss: -51.214813, total loss: 8314.119960]
[epoch 400] [emb. loss: 8355.265528, top. loss: -40.292225, total loss: 8314.973303]
[epoch 500] [emb. loss: 8446.866949, top. loss: -40.418922, total loss: 8406.448026]
[epoch 600] [emb. loss: 8570.864994, top. loss: -40.061611, total loss: 8530.803382]
[epoch 700] [emb. loss: 8522.397476, top. loss: -37.163643, total loss: 8485.233833]
[epoch 800] [emb. loss: 8517.306434, top. loss: -39.136063, total loss: 8478.170371]
[epoch 900] [emb. loss: 8544.170196, top. loss: -37.374268, total loss: 8506.795928]
[epoch 1000] [emb. loss: 8543.322056, top. loss: -37.489784, total loss: 8505.832272]
Time for embedding: 00:00:35


Conducting topologically regularized embedding for lambda_top = 100.0
[epoch 1] [emb. loss: 9376.855727, top. loss: -154.009491, total loss: 9222.846236]
[epoch 100] [emb. loss: 8599.419618, top. loss: -834.255493, total loss: 7765.164125]
[epoch 200] [emb. loss: 8765.762889, top. loss: -1308.315674, total loss: 7457.447215]
[epoch 300] [emb. loss: 8617.362082, top. loss: -1559.152100, total loss: 7058.209982]
[epoch 400] [emb. loss: 8786.222871, top. loss: -2075.254395, total loss: 6710.968476]
[epoch 500] [emb. loss: 8793.820944, top. loss: -2353.928467, total loss: 6439.892477]
[epoch 600] [emb. loss: 8986.778646, top. loss: -2795.119873, total loss: 6191.658773]
[epoch 700] [emb. loss: 9019.626057, top. loss: -3065.746826, total loss: 5953.879231]
[epoch 800] [emb. loss: 9053.186037, top. loss: -3411.338379, total loss: 5641.847658]
[epoch 900] [emb. loss: 8861.325488, top. loss: -3748.851318, total loss: 5112.474170]
[epoch 1000] [emb. loss: 9075.385470, top. loss: -4178.979980, total loss: 4896.405489]
Time for embedding: 00:00:36


for m in lambda_top_multipliers:
    # Summarize the topological and embedding losses in a data frame 
    pd_losses_m = pd.DataFrame({"epoch":range(num_epochs),
                                      "embedding (with top. reg.)":losses_lambdas[m]["losses"]["embedding"],
                                      "topological (with UMAP)":losses_lambdas[m]["losses"]["topological"] / 
                                (m * lambda_top)})

    # Plot the losses according to the number of epochs
    ax = pd_losses_m.plot(x="epoch", y="embedding (with top. reg.)", legend=False, figsize=(15, 3), color="#2c7fb8")
    ax.set_ylabel("embedding loss")
    ax2 = ax.twinx()
    pd_losses_m.plot(x="epoch", y="topological (with UMAP)", legend=False, color="#ff7f0e", ax=ax2)
    ax2.set_ylabel("topological loss")
    ax.figure.legend(bbox_to_anchor=(0.6, 0.875))
    ax.set_title("$\lambda_{{{}}}$ = {}".format("top", m * lambda_top))
    plt.show()

	mean	std
umap	0.787500	0.077951
top. opt.	0.811875	0.070786
top. reg.	0.820625	0.080763

Topological regularization of bifurcating cell trajectory embedding¶

Load data and view ordinary UMAP embedding¶

Apply topological regularization to the embedding¶

Compare with ordinary topological optimization¶

Quantitative evaluation¶

Varying threshold tau in flare loss¶

Topological regularization for different powers of the persistence lifetime¶

Topological regularization for different shape prior¶