Review of previous OCR projects, comparison of existing offerings, in-house OCR solution
OCR, or optical character recognition, is a technology that can be used to extract text from images or scanned documents. This can be useful for a variety of tasks, such as digitizing old documents, extracting data from forms, and automating data entry.
There are a number of different OCR tools available, each with its own strengths and weaknesses. Some of the most popular OCR tools include:
- Google Document AI: Google Document AI is a cloud-based OCR service that can be used to extract text from a variety of documents, including PDFs, images, and scanned documents.
- Microsoft Azure OCR: Microsoft Azure OCR is another cloud-based OCR service that offers a variety of features, including batch processing and multilingual support.
- Amazon Textract: Amazon Textract is a cloud-based OCR service that can be used to extract text from a variety of documents, including images, scanned documents, and receipts.
- Python Tesseract: Python Tesseract is an open-source OCR library that can be used to extract text from images and scanned documents.
- EasyOCR: EasyOCR is a Python OCR library that is easy to use and can be used to extract text from a variety of documents, including images, scanned documents, and receipts.
- Keras-OCR: Keras-OCR is a Python OCR library that is built on top of the Keras deep learning framework. It can be used to train custom OCR models for specific tasks.
- PaddleOCR: PaddleOCR is a Python OCR library that is built on top of the PaddlePaddle deep learning framework. It can be used to train custom OCR models for specific tasks.
To train OCR models, the FUNSD dataset from Jaume, et al (2019) was utilized. The dataset consists of 5304 relations, 9707 semantic entities, 31485 words, and 199 fully annotated forms. Form annotation, or ground truth, is stored in the JSON file format.
Dataset can be downloaded directly from Jaume website:
! wget https://guillaumejaume.github.io/FUNSD/dataset.zip
! unzip dataset.zip && mv dataset data && rm -rf dataset.zip __MACOSX
G. Jaume, H. K. Ekenel, J. Thiran "FUNSD: A Dataset for Form Understanding in Noisy Scanned Documents," 2019
from __future__ import annotations
from collections.abc import Sequence
from google.api_core.client_options import ClientOptions
from google.cloud import documentai # type: ignore
# TODO(developer): Uncomment these variables before running the sample.
# project_id = 'YOUR_PROJECT_ID'
# location = 'YOUR_PROCESSOR_LOCATION' # Format is 'us' or 'eu'
# processor_id = 'YOUR_PROCESSOR_ID' # Create processor before running sample
# processor_version = 'rc' # Refer to https://cloud.google.com/document-ai/docs/manage-processor-versions for more information
# file_path = '/path/to/local/pdf'
# mime_type = 'application/pdf' # Refer to https://cloud.google.com/document-ai/docs/file-types for supported file types
def process_document_ocr_sample(
project_id: str,
location: str,
processor_id: str,
processor_version: str,
file_path: str,
mime_type: str,
) -> None:
# Online processing request to Document AI
document = process_document(
project_id, location, processor_id, processor_version, file_path, mime_type
)
# For a full list of Document object attributes, please reference this page:
# https://cloud.google.com/python/docs/reference/documentai/latest/google.cloud.documentai_v1.types.Document
text = document.text
print(f"Full document text: {text}\n")
print(f"There are {len(document.pages)} page(s) in this document.\n")
for page in document.pages:
print(f"Page {page.page_number}:")
print_page_dimensions(page.dimension)
print_detected_langauges(page.detected_languages)
print_paragraphs(page.paragraphs, text)
print_blocks(page.blocks, text)
print_lines(page.lines, text)
print_tokens(page.tokens, text)
# Currently supported in version pretrained-ocr-v1.1-2022-09-12
if page.image_quality_scores:
print_image_quality_scores(page.image_quality_scores)
def process_document(
project_id: str,
location: str,
processor_id: str,
processor_version: str,
file_path: str,
mime_type: str,
) -> documentai.Document:
# You must set the api_endpoint if you use a location other than 'us'.
opts = ClientOptions(api_endpoint=f"{location}-documentai.googleapis.com")
client = documentai.DocumentProcessorServiceClient(client_options=opts)
# The full resource name of the processor version
# e.g. projects/{project_id}/locations/{location}/processors/{processor_id}/processorVersions/{processor_version_id}
# You must create processors before running sample code.
name = client.processor_version_path(
project_id, location, processor_id, processor_version
)
# Read the file into memory
with open(file_path, "rb") as image:
image_content = image.read()
# Load Binary Data into Document AI RawDocument Object
raw_document = documentai.RawDocument(content=image_content, mime_type=mime_type)
# Configure the process request
request = documentai.ProcessRequest(name=name, raw_document=raw_document)
result = client.process_document(request=request)
return result.document
def print_page_dimensions(dimension: documentai.Document.Page.Dimension) -> None:
print(f" Width: {str(dimension.width)}")
print(f" Height: {str(dimension.height)}")
def print_detected_langauges(
detected_languages: Sequence[documentai.Document.Page.DetectedLanguage],
) -> None:
print(" Detected languages:")
for lang in detected_languages:
code = lang.language_code
print(f" {code} ({lang.confidence:.1%} confidence)")
def print_paragraphs(
paragraphs: Sequence[documentai.Document.Page.Paragraph], text: str
) -> None:
print(f" {len(paragraphs)} paragraphs detected:")
first_paragraph_text = layout_to_text(paragraphs[0].layout, text)
print(f" First paragraph text: {repr(first_paragraph_text)}")
last_paragraph_text = layout_to_text(paragraphs[-1].layout, text)
print(f" Last paragraph text: {repr(last_paragraph_text)}")
def print_blocks(blocks: Sequence[documentai.Document.Page.Block], text: str) -> None:
print(f" {len(blocks)} blocks detected:")
first_block_text = layout_to_text(blocks[0].layout, text)
print(f" First text block: {repr(first_block_text)}")
last_block_text = layout_to_text(blocks[-1].layout, text)
print(f" Last text block: {repr(last_block_text)}")
def print_lines(lines: Sequence[documentai.Document.Page.Line], text: str) -> None:
print(f" {len(lines)} lines detected:")
first_line_text = layout_to_text(lines[0].layout, text)
print(f" First line text: {repr(first_line_text)}")
last_line_text = layout_to_text(lines[-1].layout, text)
print(f" Last line text: {repr(last_line_text)}")
def print_tokens(tokens: Sequence[documentai.Document.Page.Token], text: str) -> None:
print(f" {len(tokens)} tokens detected:")
first_token_text = layout_to_text(tokens[0].layout, text)
first_token_break_type = tokens[0].detected_break.type_.name
print(f" First token text: {repr(first_token_text)}")
print(f" First token break type: {repr(first_token_break_type)}")
last_token_text = layout_to_text(tokens[-1].layout, text)
last_token_break_type = tokens[-1].detected_break.type_.name
print(f" Last token text: {repr(last_token_text)}")
print(f" Last token break type: {repr(last_token_break_type)}")
def print_image_quality_scores(
image_quality_scores: documentai.Document.Page.ImageQualityScores,
) -> None:
print(f" Quality score: {image_quality_scores.quality_score:.1%}")
print(" Detected defects:")
for detected_defect in image_quality_scores.detected_defects:
print(f" {detected_defect.type_}: {detected_defect.confidence:.1%}")
def layout_to_text(layout: documentai.Document.Page.Layout, text: str) -> str:
"""
Document AI identifies text in different parts of the document by their
offsets in the entirety of the document's text. This function converts
offsets to a string.
"""
response = ""
# If a text segment spans several lines, it will
# be stored in different text segments.
for segment in layout.text_anchor.text_segments:
start_index = int(segment.start_index)
end_index = int(segment.end_index)
response += text[start_index:end_index]
return responsefrom azure.cognitiveservices.vision.computervision import ComputerVisionClient
from msrest.authentication import CognitiveServicesCredentials
from azure.cognitiveservices.vision.computervision.models import OperationStatusCodes
import time
from dotenv import load_dotenv
import os
def main():
try:
# Get Configuration Settings
load_dotenv()
endpoint = os.getenv('COG_SERVICE_ENDPOINT')
key = os.getenv('COG_SERVICE_KEY')
# Authenticate Computer Vision client
computervision_client = ComputerVisionClient(endpoint, CognitiveServicesCredentials(key))
# Extract test
images_folder = os.path.join (os.path.dirname(os.path.abspath(__file__)), "images")
read_image_path = os.path.join (images_folder, "notes1.jpg")
get_text(read_image_path,computervision_client)
print('\n')
read_image_path = os.path.join (images_folder, "notes2.jpg")
get_text(read_image_path,computervision_client)
except Exception as ex:
print(ex)
def get_text(image_file,computervision_client):
# Open local image file
with open(image_file, "rb") as image:
# Call the API
read_response = computervision_client.read_in_stream(image, raw=True)
# Get the operation location (URL with an ID at the end)
read_operation_location = read_response.headers["Operation-Location"]
# Grab the ID from the URL
operation_id = read_operation_location.split("/")[-1]
# Retrieve the results
while True:
read_result = computervision_client.get_read_result(operation_id)
if read_result.status.lower() not in ['notstarted', 'running']:
break
time.sleep(1)
# Get the detected text
if read_result.status == OperationStatusCodes.succeeded:
for page in read_result.analyze_result.read_results:
for line in page.lines:
# Print line
print(line.text)
if __name__ == "__main__":
main()# Import the required modules
import pytesseract
from PIL import Image
# Set the path for the Tesseract executable
pytesseract.pytesseract.tesseract_cmd = r'C:\Program Files\Tesseract-OCR\tesseract.exe'
# Open the image using Pillow library
img = Image.open('image.png')
# Convert the image to grayscale
img = img.convert('L')
# Perform OCR using Tesseract
text = pytesseract.image_to_string(img)
# Print the extracted text
print(text)from pathlib import Path
import aiopytesseract
# list all available languages by tesseract installation
await aiopytesseract.languages()
await aiopytesseract.get_languages()
# tesseract version
await aiopytesseract.tesseract_version()
await aiopytesseract.get_tesseract_version()
# tesseract parameters
await aiopytesseract.tesseract_parameters()
# confidence only info
await aiopytesseract.confidence("tests/samples/file-sample_150kB.png")
# deskew info
await aiopytesseract.deskew("tests/samples/file-sample_150kB.png")
# extract text from an image: locally or bytes
await aiopytesseract.image_to_string("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_string(
Path("tests/samples/file-sample_150kB.png")read_bytes(), dpi=220, lang='eng+por'
)
# box estimates
await aiopytesseract.image_to_boxes("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_boxes(Path("tests/samples/file-sample_150kB.png")
# boxes, confidence and page numbers
await aiopytesseract.image_to_data("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_data(Path("tests/samples/file-sample_150kB.png")
# information about orientation and script detection
await aiopytesseract.image_to_osd("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_osd(Path("tests/samples/file-sample_150kB.png")
# generate a searchable PDF
await aiopytesseract.image_to_pdf("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_pdf(Path("tests/samples/file-sample_150kB.png")
# generate HOCR output
await aiopytesseract.image_to_hocr("tests/samples/file-sample_150kB.png")
await aiopytesseract.image_to_hocr(Path("tests/samples/file-sample_150kB.png")
# multi ouput
async with aiopytesseract.run(
Path('tests/samples/file-sample_150kB.png').read_bytes(),
'output',
'alto tsv txt'
) as resp:
# will generate (output.xml, output.tsv and output.txt)
print(resp)
alto_file, tsv_file, txt_file = respNote: This tutorial mainly introduces the usage of PP-OCR series models, please refer to PP-Structure Quick Start for the quick use of document analysis related functions.
If you do not have a Python environment, please refer to Environment Preparation.
-
If you have CUDA 9 or CUDA 10 installed on your machine, please run the following command to install
python -m pip install paddlepaddle-gpu -i https://pypi.tuna.tsinghua.edu.cn/simple
-
If you have no available GPU on your machine, please run the following command to install the CPU version
python -m pip install paddlepaddle -i https://pypi.tuna.tsinghua.edu.cn/simple
For more software version requirements, please refer to the instructions in Installation Document for operation.
pip install "paddleocr>=2.0.1" # Recommend to use version 2.0.1+-
For windows users: If you getting this error
OSError: [WinError 126] The specified module could not be foundwhen you install shapely on windows. Please try to download Shapely whl file here.Reference: Solve shapely installation on windows
PaddleOCR provides a series of test images, click here to download, and then switch to the corresponding directory in the terminal
cd /path/to/ppocr_imgIf you do not use the provided test image, you can replace the following --image_dir parameter with the corresponding test image path
-
Detection, direction classification and recognition: set the parameter
--use_gpu falseto disable the gpu devicepaddleocr --image_dir ./imgs_en/img_12.jpg --use_angle_cls true --lang en --use_gpu false
Output will be a list, each item contains bounding box, text and recognition confidence
[[[441.0, 174.0], [1166.0, 176.0], [1165.0, 222.0], [441.0, 221.0]], ('ACKNOWLEDGEMENTS', 0.9971134662628174)] [[[403.0, 346.0], [1204.0, 348.0], [1204.0, 384.0], [402.0, 383.0]], ('We would like to thank all the designers and', 0.9761400818824768)] [[[403.0, 396.0], [1204.0, 398.0], [1204.0, 434.0], [402.0, 433.0]], ('contributors who have been involved in the', 0.9791957139968872)] ......
pdf file is also supported, you can infer the first few pages by using the
page_numparameter, the default is 0, which means infer all pagespaddleocr --image_dir ./xxx.pdf --use_angle_cls true --use_gpu false --page_num 2
-
Only detection: set
--rectofalsepaddleocr --image_dir ./imgs_en/img_12.jpg --rec falseOutput will be a list, each item only contains bounding box
[[397.0, 802.0], [1092.0, 802.0], [1092.0, 841.0], [397.0, 841.0]] [[397.0, 750.0], [1211.0, 750.0], [1211.0, 789.0], [397.0, 789.0]] [[397.0, 702.0], [1209.0, 698.0], [1209.0, 734.0], [397.0, 738.0]] ......
-
Only recognition: set
--dettofalsepaddleocr --image_dir ./imgs_words_en/word_10.png --det false --lang enOutput will be a list, each item contains text and recognition confidence
['PAIN', 0.9934559464454651]
Version
paddleocr uses the PP-OCRv3 model by default(--ocr_version PP-OCRv3). If you want to use other versions, you can set the parameter --ocr_version, the specific version description is as follows:
| version name | description |
|---|---|
| PP-OCRv3 | support Chinese and English detection and recognition, direction classifier, support multilingual recognition |
| PP-OCRv2 | only supports Chinese and English detection and recognition, direction classifier, multilingual model is not updated |
| PP-OCR | support Chinese and English detection and recognition, direction classifier, support multilingual recognition |
If you want to add your own trained model, you can add model links and keys in paddleocr and recompile.
More whl package usage can be found in whl package
PaddleOCR currently supports 80 languages, which can be switched by modifying the --lang parameter.
paddleocr --image_dir ./doc/imgs_en/254.jpg --lang=en
[[[67.0, 51.0], [327.0, 46.0], [327.0, 74.0], [68.0, 80.0]], ('PHOCAPITAL', 0.9944712519645691)]
[[[72.0, 92.0], [453.0, 84.0], [454.0, 114.0], [73.0, 122.0]], ('107 State Street', 0.9744491577148438)]
[[[69.0, 135.0], [501.0, 125.0], [501.0, 156.0], [70.0, 165.0]], ('Montpelier Vermont', 0.9357033967971802)]
......
Commonly used multilingual abbreviations include
| Language | Abbreviation | Language | Abbreviation | Language | Abbreviation | ||
|---|---|---|---|---|---|---|---|
| Chinese & English | ch | French | fr | Japanese | japan | ||
| English | en | German | german | Korean | korean | ||
| Chinese Traditional | chinese_cht | Italian | it | Russian | ru |
A list of all languages and their corresponding abbreviations can be found in Multi-Language Model Tutorial
- detection, angle classification and recognition:
from paddleocr import PaddleOCR,draw_ocr
# Paddleocr supports Chinese, English, French, German, Korean and Japanese.
# You can set the parameter `lang` as `ch`, `en`, `fr`, `german`, `korean`, `japan`
# to switch the language model in order.
ocr = PaddleOCR(use_angle_cls=True, lang='en') # need to run only once to download and load model into memory
img_path = './imgs_en/img_12.jpg'
result = ocr.ocr(img_path, cls=True)
for idx in range(len(result)):
res = result[idx]
for line in res:
print(line)
# draw result
from PIL import Image
result = result[0]
image = Image.open(img_path).convert('RGB')
boxes = [line[0] for line in result]
txts = [line[1][0] for line in result]
scores = [line[1][1] for line in result]
im_show = draw_ocr(image, boxes, txts, scores, font_path='./fonts/simfang.ttf')
im_show = Image.fromarray(im_show)
im_show.save('result.jpg')Output will be a list, each item contains bounding box, text and recognition confidence
[[[441.0, 174.0], [1166.0, 176.0], [1165.0, 222.0], [441.0, 221.0]], ('ACKNOWLEDGEMENTS', 0.9971134662628174)]
[[[403.0, 346.0], [1204.0, 348.0], [1204.0, 384.0], [402.0, 383.0]], ('We would like to thank all the designers and', 0.9761400818824768)]
[[[403.0, 396.0], [1204.0, 398.0], [1204.0, 434.0], [402.0, 433.0]], ('contributors who have been involved in the', 0.9791957139968872)]
......Visualization of results
If the input is a PDF file, you can refer to the following code for visualization
from paddleocr import PaddleOCR, draw_ocr
# Paddleocr supports Chinese, English, French, German, Korean and Japanese.
# You can set the parameter `lang` as `ch`, `en`, `fr`, `german`, `korean`, `japan`
# to switch the language model in order.
ocr = PaddleOCR(use_angle_cls=True, lang="ch", page_num=2) # need to run only once to download and load model into memory
img_path = './xxx.pdf'
result = ocr.ocr(img_path, cls=True)
for idx in range(len(result)):
res = result[idx]
for line in res:
print(line)
# draw result
import fitz
from PIL import Image
import cv2
import numpy as np
imgs = []
with fitz.open(img_path) as pdf:
for pg in range(0, pdf.pageCount):
page = pdf[pg]
mat = fitz.Matrix(2, 2)
pm = page.getPixmap(matrix=mat, alpha=False)
# if width or height > 2000 pixels, don't enlarge the image
if pm.width > 2000 or pm.height > 2000:
pm = page.getPixmap(matrix=fitz.Matrix(1, 1), alpha=False)
img = Image.frombytes("RGB", [pm.width, pm.height], pm.samples)
img = cv2.cvtColor(np.array(img), cv2.COLOR_RGB2BGR)
imgs.append(img)
for idx in range(len(result)):
res = result[idx]
image = imgs[idx]
boxes = [line[0] for line in res]
txts = [line[1][0] for line in res]
scores = [line[1][1] for line in res]
im_show = draw_ocr(image, boxes, txts, scores, font_path='doc/fonts/simfang.ttf')
im_show = Image.fromarray(im_show)
im_show.save('result_page_{}.jpg'.format(idx))In this section, you have mastered the use of PaddleOCR whl package.
PaddleOCR is a rich and practical OCR tool library that get through the whole process of data production, model training, compression, inference and deployment, please refer to the tutorials to start the journey of PaddleOCR.