ViT Fruit Ripeness Classifier
A fruit ripeness classification model combining Vision Transformer (ViT) feature extraction with Logistic Regression for fast, accurate inference on CPU or GPU.
Model Description
This model classifies the ripeness condition of apples, bananas, and oranges into three categories:
- Fresh - Ready to eat
- Unripe - Needs more time to ripen
- Rotten - Past optimal consumption
Architecture
- Feature Extractor: ViT Base Patch-16 (
google/vit-base-patch16-224) - Classifier: Scikit-learn Logistic Regression
- Feature Dimension: 768-dim pooled output from ViT
- Total Classes: 9 (3 fruits Γ 3 ripeness states)
Supported Classes
| Class | Description |
|---|---|
freshapples |
Fresh, ready-to-eat apples |
freshbanana |
Fresh, ripe bananas |
freshoranges |
Fresh, ripe oranges |
rottenapples |
Overripe/rotten apples |
rottenbanana |
Overripe/rotten bananas |
rottenoranges |
Overripe/rotten oranges |
unripe apple |
Unripe apples |
unripe banana |
Unripe bananas |
unripe orange |
Unripe oranges |
Quick Start
Installation
pip install torch torchvision transformers scikit-learn pillow joblib numpy huggingface_hub
First Run Notes
- Automatic Downloads: The model files (~350-400MB) download automatically on first run
- No Manual Downloads: You don't need to manually download any model files
- Internet Required: Only for the first run; subsequent runs work offline using cached files
- Time: First run takes 2-5 minutes for downloads; later runs are instant
Single Image Inference
import json
import joblib
from pathlib import Path
from PIL import Image
import torch
import numpy as np
from huggingface_hub import hf_hub_download, HfApi
from transformers import AutoImageProcessor, ViTModel
import warnings
# ----------------- CONFIG -----------------
REPO_ID = "Meeteshn/vit_fruit_ripeness_classifier"
DEVICE = "cuda" if torch.cuda.is_available() else "cpu"
NESTED_FOLDER = "vit_fruit_ripeness_updated" # your repo uses this nested folder
TOP_K = 5
# ------------------------------------------
def hf_download_try(repo_id: str, filename: str, nested_folder: str = NESTED_FOLDER):
"""
Try to download `filename` from repo root, then from nested_folder/filename.
Returns local path to downloaded file or raises an informative error.
"""
candidates = [filename, f"{nested_folder}/{filename}"]
last_exc = None
for f in candidates:
try:
print(f"Trying to download '{f}' from '{repo_id}'...")
path = hf_hub_download(repo_id=repo_id, filename=f)
print("Downloaded:", path)
return path
except Exception as e:
print(f"Not found at '{f}': {e}")
last_exc = e
raise RuntimeError(f"Could not download '{filename}' from repo '{repo_id}'. Last error: {last_exc}")
def load_processor_and_backbone(repo_id: str, nested_folder: str = NESTED_FOLDER, device: str = DEVICE):
"""
Try several likely subfolder locations for processor/backbone.
Returns (processor, backbone).
"""
# candidate subfolders for processor
proc_candidates = [
"processor",
f"{nested_folder}/processor",
"", # no subfolder (root)
]
last_exc = None
for sub in proc_candidates:
try:
if sub == "":
print(f"Trying AutoImageProcessor.from_pretrained('{repo_id}')")
processor = AutoImageProcessor.from_pretrained(repo_id, use_fast=True)
else:
print(f"Trying AutoImageProcessor.from_pretrained('{repo_id}', subfolder='{sub}')")
processor = AutoImageProcessor.from_pretrained(repo_id, subfolder=sub, use_fast=True)
# now try backbone with matching guessed subfolder
backbone_sub = sub.replace("processor", "vit_backbone") if sub and "processor" in sub else ("vit_backbone" if sub == "" else f"{nested_folder}/vit_backbone")
try:
print(f"Trying ViTModel.from_pretrained('{repo_id}', subfolder='{backbone_sub}')")
backbone = ViTModel.from_pretrained(repo_id, subfolder=backbone_sub)
except Exception as e_backbone:
# final fallback: try root vit_backbone
print(f"Backbone attempt failed for sub='{backbone_sub}': {e_backbone}. Trying root 'vit_backbone'.")
backbone = ViTModel.from_pretrained(repo_id, subfolder="vit_backbone")
backbone.to(device)
backbone.eval()
print(f"Loaded processor/backbone from subfolder='{sub or 'root'}'")
return processor, backbone
except Exception as e:
print(f"Processor load failed for sub='{sub}': {e}")
last_exc = e
# ultimate fallback: official ViT from hub
warnings.warn("Could not load processor/backbone from repo; falling back to official 'google/vit-base-patch16-224'.")
processor = AutoImageProcessor.from_pretrained("google/vit-base-patch16-224", use_fast=True)
backbone = ViTModel.from_pretrained("google/vit-base-patch16-224")
backbone.to(device)
backbone.eval()
return processor, backbone
# ----------------- Load assets (robust) -----------------
processor, backbone = load_processor_and_backbone(REPO_ID, nested_folder=NESTED_FOLDER, device=DEVICE)
# Download sklearn artifacts (try root then nested)
scaler_path = hf_download_try(REPO_ID, "scaler.joblib", nested_folder=NESTED_FOLDER)
clf_path = hf_download_try(REPO_ID, "logistic_model.joblib", nested_folder=NESTED_FOLDER)
metadata_path = hf_download_try(REPO_ID, "metadata.json", nested_folder=NESTED_FOLDER)
scaler = joblib.load(scaler_path)
clf = joblib.load(clf_path)
metadata = json.loads(Path(metadata_path).read_text(encoding="utf-8"))
classes = metadata["classes"]
# ----------------- Prediction function -----------------
def predict(image_path: str):
"""Predict ripeness condition for a single image."""
img = Image.open(image_path).convert("RGB")
inputs = processor(images=img, return_tensors="pt")
pixel_values = inputs["pixel_values"].to(DEVICE)
with torch.no_grad():
out = backbone(pixel_values=pixel_values, return_dict=True)
pooled = getattr(out, "pooler_output", None)
if pooled is None:
pooled = out.last_hidden_state[:, 0, :]
feat = pooled.cpu().numpy()
feat_scaled = scaler.transform(feat)
# get probabilities (works for sklearn logistic / classifiers with predict_proba)
if hasattr(clf, "predict_proba"):
probs = clf.predict_proba(feat_scaled)[0]
else:
# fallback for classifiers without predict_proba
dec = clf.decision_function(feat_scaled)[0]
exp = np.exp(dec - np.max(dec))
probs = exp / exp.sum()
idx = int(np.argmax(probs))
return classes[idx], float(probs[idx]), {classes[i]: float(probs[i]) for i in range(len(classes))}
# ----------------- Example usage -----------------
if __name__ == "__main__":
sample_image = "my_apple.jpg" # change as needed
label, prob, all_probs = predict(sample_image)
print(f"Prediction: {label} ({prob*100:.2f}%)")
print("\nTop probabilities:")
for cls, p in sorted(all_probs.items(), key=lambda x: -x[1])[:TOP_K]:
print(f" {cls}: {p*100:.2f}%")
Batch Prediction
from pathlib import Path
import csv
def batch_predict(folder_path: str, output_csv: str = "predictions.csv"):
"""Predict ripeness for all images in a folder."""
folder = Path(folder_path)
with open(output_csv, "w", newline="", encoding="utf-8") as f:
writer = csv.writer(f)
writer.writerow(["filename", "predicted_label", "probability"])
for img_path in sorted(folder.rglob("*")):
if img_path.suffix.lower() not in [".jpg", ".jpeg", ".png", ".bmp"]:
continue
label, prob, _ = predict(str(img_path))
writer.writerow([img_path.name, label, f"{prob*100:.2f}%"])
print(f"Predictions saved to {output_csv}")
# Usage
batch_predict("path/to/images")
Example Output
Prediction: rottenapples (71.24%)
Top 5 probabilities:
rottenapples: 71.24%
rottenbanana: 12.35%
freshapples: 6.12%
unripe apple: 4.89%
freshoranges: 2.31%
Repository Structure
vit_fruit_ripeness_updated/
βββ processor/ # AutoImageProcessor configuration
βββ vit_backbone/ # ViT feature extractor weights
βββ logistic_model.joblib # Trained classifier
βββ scaler.joblib # Feature scaler
βββ metadata.json # Class labels and metadata
βββ features_extracted.npz # (Optional) Cached features
Performance Notes
- Best Results: Fruit is centered and clearly visible in the image
- Works Well: Smartphone photos, typical market/kitchen images
- Challenges: Heavy background clutter, extreme lighting conditions, unusual fruit varieties
- Uncertainty Handling: Use top-K probabilities to assess prediction confidence
Use Cases
- Quality control in fruit sorting facilities
- Smart grocery shopping apps
- Food waste reduction systems
- Educational tools for agriculture
- Retail inventory management
Technical Details
- Input Size: 224Γ224 pixels (automatically resized)
- Inference Speed: ~50-100ms per image (GPU), ~200-500ms (CPU)
- Memory Usage: ~500MB (model weights)
- Training: No training required for inference
License
MIT License - See LICENSE file for details
Author
Meetesh Nagrecha
Acknowledgments
- Base model:
google/vit-base-patch16-224 - Framework: Hugging Face Transformers & Scikit-learn
Citation
If you use this model in your research, please cite:
@misc{vit-fruit-ripeness-classifier,
author = {Nagrecha, Meetesh},
title = {ViT Fruit Ripeness Classifier},
year = {2024},
publisher = {Hugging Face},
howpublished = {\url{https://huggingface.co/Meeteshn/vit_fruit_ripeness_classifier}}
}
Model tree for Meeteshn/vit_fruit_ripeness_classifier
Base model
google/vit-base-patch16-224