enabled multicore simulation for multiple sims

2025-11-23 14:24:10 -06:00
parent 2fea7302bf
commit 138c04f7a1
1 changed files with 81 additions and 75 deletions
--- a/MAGLEV_DIGITALTWIN_PYTHON/simulateMultipleWithNoise.py
+++ b/MAGLEV_DIGITALTWIN_PYTHON/simulateMultipleWithNoise.py
@@ -10,9 +10,13 @@ from utils import euler2dcm, fmag2, initialize_magnetic_characteristics, reset_m
 from simulate import simulate_maglev_control
 from visualize import visualize_quad
 import os
+from concurrent.futures import ProcessPoolExecutor
+import multiprocessing

 # ===== SIMULATION CONFIGURATION =====
 NUM_TRIALS = 5  # Number of trials to run
+NUM_CORES_LIMIT = 8 # Max number of CPU cores to use for simulations 
+# (min of this and num of cores on ur computer will be chosen.)
 NOISE_LEVEL = 0.1  # Standard deviation of noise (5%)
 # =====================================

@@ -86,7 +90,7 @@ def generate_parameter_report(trial_num, quad_params, output_dir):


 def run_single_trial(trial_num, Tsim, delt, ref_gap, z0, output_dir):
-    """Run a single simulation trial with randomized parameters"""
+    """Run a single simulation trial with randomized parameters, including all visualizations"""
    
    # Reset and reinitialize noise for this trial
    reset_parameter_variations()
@@ -113,7 +117,7 @@ def run_single_trial(trial_num, Tsim, delt, ref_gap, z0, output_dir):
    oversampFact = 10
    
    # Check nominal gap
-    print(f"Force check: {4*fmag2(0, 10.830e-3) - m*g}")
+    print(f"Trial {trial_num}: Force check: {4*fmag2(0, 10.830e-3) - m*g}")
    
    # SET REFERENCE HERE
    ref_gap = 10.830e-3  # from python code
@@ -166,9 +170,9 @@ def run_single_trial(trial_num, Tsim, delt, ref_gap, z0, output_dir):
    generate_parameter_report(trial_num, quad_params, output_dir)
    
    # Run simulation
-    print(f"  Running simulation for trial {trial_num}...")
+    print(f"Trial {trial_num}: Running simulation...")
    P0 = simulate_maglev_control(R, S, P)
-    print(f"  Trial {trial_num} simulation complete!")
+    print(f"Trial {trial_num}: Simulation complete!")
    
    # Extract results
    tVec_out = P0['tVec']
@@ -179,7 +183,7 @@ def run_single_trial(trial_num, Tsim, delt, ref_gap, z0, output_dir):
    currents = state['currents']
    
    # Generate 3D visualization (GIF) without displaying
-    print(f"  Generating 3D visualization for trial {trial_num}...")
+    print(f"Trial {trial_num}: Generating 3D visualization...")
    S2 = {
        'tVec': tVec_out,
        'rMat': rMat,
@@ -195,55 +199,12 @@ def run_single_trial(trial_num, Tsim, delt, ref_gap, z0, output_dir):
    # Calculate forces
    Fm = fmag2(currents[:, 0], gaps[:, 0])
    
-    return {
-        'tVec': tVec_out,
-        'gaps': gaps,
-        'currents': currents,
-        'Fm': Fm,
-        'quad_params': quad_params
-    }
-
-
-def main():
-    """Main simulation script - runs multiple trials"""
-    
-    # Create output directory if it doesn't exist
-    output_dir = 'sim_results_multi'
-    os.makedirs(output_dir, exist_ok=True)
-    
-    # Total simulation time, in seconds
-    Tsim = 2
-    
-    # Update interval, in seconds
-    delt = 0.005  # sampling interval
-    
-    # Reference gap and initial condition
-    ref_gap = 10.830e-3
-    z0 = ref_gap - 2e-3
-    
-    print(f"\n{'='*60}")
-    print(f"Running {NUM_TRIALS} trials with noise level {NOISE_LEVEL*100:.1f}%")
-    print(f"{'='*60}\n")
-    
-    # Run all trials
-    trial_results = []
-    for trial in range(1, NUM_TRIALS + 1):
-        print(f"Trial {trial}/{NUM_TRIALS}")
-        result = run_single_trial(trial, Tsim, delt, ref_gap, z0, output_dir)
-        trial_results.append(result)
-        print()
-    
-    # Create individual plots for each trial
-    print("Generating plots...")
-    for i, result in enumerate(trial_results, 1):
-        tVec_out = result['tVec']
-        gaps = result['gaps']
-        currents = result['currents']
-        Fm = result['Fm']
+    # Generate plots immediately after simulation
+    print(f"Trial {trial_num}: Generating plots...")
    
    # Create plots for this trial
    fig = plt.figure(figsize=(12, 8))
-        fig.suptitle(f'Trial {i} - Noise Level {NOISE_LEVEL*100:.1f}%', fontsize=14, fontweight='bold')
+    fig.suptitle(f'Trial {trial_num} - Noise Level {NOISE_LEVEL*100:.1f}%', fontsize=14, fontweight='bold')
    
    # Plot 1: Gaps
    ax1 = plt.subplot(3, 1, 1)
@@ -275,12 +236,10 @@ def main():
    plt.grid(True)
    
    plt.tight_layout()
-        plt.savefig(f'{output_dir}/trial_{i:02d}_results.png', dpi=150)
-        print(f"  Saved trial {i} plot")
+    plt.savefig(f'{output_dir}/trial_{trial_num:02d}_results.png', dpi=150)
    plt.close()
    
    # FFT for this trial
-        oversampFact = 10
    Fs = 1/delt * oversampFact
    L = len(tVec_out)
    
@@ -289,15 +248,62 @@ def main():
    
    fig2 = plt.figure(figsize=(10, 6))
    plt.semilogx(frequencies, np.abs(Y), linewidth=2)
-        plt.title(f"FFT Spectrum - Trial {i}")
+    plt.title(f"FFT Spectrum - Trial {trial_num}")
    plt.xlabel("Frequency (Hz)")
    plt.ylabel("Magnitude")
    plt.ylim([0, np.max(np.abs(Y[1:])) * 1.05])
    plt.grid(True)
-        plt.savefig(f'{output_dir}/trial_{i:02d}_fft.png', dpi=150)
-        print(f"  Saved trial {i} FFT")
+    plt.savefig(f'{output_dir}/trial_{trial_num:02d}_fft.png', dpi=150)
    plt.close()
    
+    print(f"Trial {trial_num}: COMPLETE (all outputs generated)")
+    
+    return {
+        'tVec': tVec_out,
+        'gaps': gaps,
+        'currents': currents,
+        'Fm': Fm,
+        'quad_params': quad_params
+    }
+
+
+def main():
+    """Main simulation script - runs multiple trials"""
+    
+    # Create output directory if it doesn't exist
+    output_dir = 'sim_results_multi'
+    os.makedirs(output_dir, exist_ok=True)
+    
+    # Total simulation time, in seconds
+    Tsim = 2
+    
+    # Update interval, in seconds
+    delt = 0.005  # sampling interval
+    
+    # Reference gap and initial condition
+    ref_gap = 10.830e-3
+    z0 = ref_gap - 2e-3
+    
+    print(f"\n{'='*60}")
+    print(f"Running {NUM_TRIALS} trials with noise level {NOISE_LEVEL*100:.1f}%")
+    num_cores = min(multiprocessing.cpu_count(), NUM_CORES_LIMIT)
+    print(f"Using {num_cores} CPU cores for parallel processing")
+    print(f"{'='*60}\n")
+    
+    # Run all trials in parallel (each trial does simulation + visualization + plots)
+    trial_results = []
+    with ProcessPoolExecutor(max_workers=num_cores) as executor:
+        # Submit all trials
+        futures = [
+            executor.submit(run_single_trial, trial, Tsim, delt, ref_gap, z0, output_dir)
+            for trial in range(1, NUM_TRIALS + 1)
+        ]
+        
+        # Collect results as they complete
+        for future in futures:
+            result = future.result()
+            trial_results.append(result)
+    
    # Create overlay comparison plots
    print("\nGenerating comparison plots...")