1. rembg
rembgÊÇÒ»¸öÇ¿´óµÄPython¿â£¬ÓÃÓÚͼÏñ±³¾°µÄ×Ô¶¯È¥³ý¡£Ëü»ùÓÚÉî¶ÈѧϰºÍÈ˹¤ÖÇÄܼ¼Êõ£¬Äܹ»¸ß¶È׼ȷµØ½«Í¼ÏñÖеı³¾°¿Ù³ö£¬ÁôÏÂÇ°¾°Í¼Ïñ¡£
¡¸°²×°rembg¡¹
pip install rembg
¡¸Ê¾Àý¡¹
# Importing libraries
from rembg import remove
import cv2
# path of input image (my file: image.jpeg)
input_path = 'demo.jpg'
# path for saving output image and saving as a output.jpeg
output_path = 'output.jpg'
# Reading the input image
input = cv2.imread(input_path)
# Removing background
output = remove(input)
# Saving file
cv2.imwrite(output_path, output)
2. Ipyvolume
IpyvolumeÊÇÒ»¸ö»ùÓÚJupyter NotebookµÄPython¿â£¬ÓÃÓÚ´´½¨½»»¥Ê½µÄ3D¿ÉÊÓ»¯ºÍ¶¯»¡£ËüÌṩÁ˷ḻµÄ¹¦Äܺ͹¤¾ß£¬Ê¹µÃÔÚNotebookÖпÉÊÓ»¯Êý¾Ý±äµÃ¸ü¼Ó¼òµ¥ºÍÖ±¹Û¡£
¡¸Ê¾Àý´úÂ롹
from colormaps import parula
X = np.arange(-5, 5, 0.25*1)
Y = np.arange(-5, 5, 0.25*1)
X, Y = np.meshgrid(X, Y)
R = np.sqrt(X**2 + Y**2)
Z = np.sin(R)
colormap = parula
znorm = Z - Z.min()
znorm /= znorm.ptp()
znorm.min(), znorm.max()
color = colormap(znorm)
ipv.figure()
mesh = ipv.plot_surface(X, Z, Y, color=color[...,:3])
ipv.show()
3. Pandas-Bokeh
Pandas-BokehÊÇÒ»¸öʹÓÃBokehΪPandasÊý¾ÝÖ¡Ìṩ½»»¥Ê½»æͼµÄ¿â£¬Ëü¶ÔÓÚ´´½¨½»»¥Ê½¿ÉÊÓ»¯Êý¾Ý·Ç³£ÓÐÓá£
¡¸°²×°pandas-bokeh¡¹
pip install pandas-bokeh
¡¸½»»¥Ê½¿ÉÊÓ»¯Ð§¹û¡¹
¡¸Ê¾Àý´úÂ롹
import pandas as pd
import pandas_bokeh
data = {
'fruits':
['Apples', 'Pears', 'Nectarines', 'Plums', 'Grapes', 'Strawberries'],
'2015': [2, 1, 4, 3, 2, 4],
'2016': [5, 3, 3, 2, 4, 6],
'2017': [3, 2, 4, 4, 5, 3]
}
df = pd.DataFrame(data).set_index("fruits")
p_bar = df.plot_bokeh.bar(
ylabel="Price per Unit [€]",
title="Fruit prices per Year",
alpha=0.6)
4. Humanize
HumanizeÊÇÒ»¸öPython¿â£¬Ö¼ÔÚ½«¸´ÔÓµÄÊý¾ÝÀàÐͺ͵¥Î»×ª»»Îª¸üÒ׶ÁµÄÐÎʽ£¬ÒÔÔö¼ÓÈËÀà¿ÉÀí½âÐÔ¡£ËüÌṩÁËһЩÓÐÓõĺ¯Êý£¬ÓÃÓÚ½«Êý×Ö¡¢Ê±¼ä¡¢Îļþ´óСµÈת»»Îª¸üÓѺúͿɶÁÐÔÇ¿µÄ¸ñʽ¡£
ʹÓÃHumanize¿â£¬Äã¿ÉÒÔ½«ÕûÊýת»»Îª´øÓжººÅµÄÒ׶ÁÐÎʽ£¬ÀýÈ罫1000ת»»Îª"1,000"£»½«Ê±¼ä¼ä¸ôת»»Îª¸ü¾ßÃèÊöÐÔµÄÐÎʽ£¬ÀýÈ罫60Ãëת»»Îª"1·ÖÖÓ"£»½«×Ö½ÚÊýת»»Îª¸üÒ×Àí½âµÄÎļþ´óС±íʾ£¬ÀýÈ罫1024ת»»Îª"1KB"¡£
¡¸°²×°Humanize¡¹
pip install Humanize
¡¸Ê¾Àý£¨integers£©¡¹
import humanize
import datetime as dt
a = humanize.intcomma(951009)
b = humanize.intword(10046328394)
print(a)
print(b)
Êä³ö£º
951,009 10.0 billion
¡¸Ê¾Àý£¨Date£¦Time£©¡¹
import humanize
import datetime as dt
a = humanize.naturaldate(dt.date(2023, 9,7))
b = humanize.naturalday(dt.date(2023, 9,7))
print(a)
print(b)
Êä³ö£º
today
today
5. Pendulum
PendulumÀ©Õ¹ÁËÄÚÖõÄPython DateTimeÄ£¿é£¬Ìí¼ÓÁËÒ»¸ö¸üÖ±¹ÛµÄAPI£¬ÓÃÓÚ´¦ÀíʱÇø£¬¶ÔÈÕÆÚºÍʱ¼ä½øÐвÙ×÷£¬ÈçÌí¼Óʱ¼ä¼ä¸ô¡¢É¾È¥ÈÕÆÚÒÔ¼°ÔÚʱÇøÖ®¼ä½øÐÐת»»¡£ËüΪ¸ñʽ»¯ÈÕÆÚºÍʱ¼äÌṩÁËÒ»¸ö¼òµ¥¡¢ÈËÐÔ»¯µÄAPI¡£
¡¸°²×°Pendulum¡¹
pip install pendulum
¡¸Ê¾Àý¡¹
# import library
import pendulum
dt = pendulum.datetime(2023, 8, 31)
print(dt)
#local() creates datetime instance with local timezone
local = pendulum.local(2023, 8, 31)
print("Local Time:", local)
print("Local Time Zone:", local.timezone.name)
# Printing UTC time
utc = pendulum.now('UTC')
print("Current UTC time:", utc)
# Converting UTC timezone into Europe/Paris time
europe = utc.in_timezone('Europe/Paris')
print("Current time in Paris:", europe)
Êä³ö£º
2023-08-31T00:00:00+00:00
Local Time: 2023-08-31T00:00:00+08:00
Local Time Zone: Asia/Shanghai Current
UTC time: 2023-09-07T04:06:05.436553+00:00
Current time in Paris: 2023-09-07T06:06:05.436553+02:00
6. Sketchpy
SketchpyÊÇÒ»¸öÓÃÓÚ¶ÔͼÏñ½øÐж¯»»æÖƵÄPythonÄ£¿é¡£sketchpyÄ£¿éÊÇÔÚPythonÖеÄturtleÄ£¿éÖ®ÉÏ´´½¨µÄ¡£
¡¸°²×°Sketchpy¡¹
pip install sketchpy
¡¸Ê¾Àý-ʹÓà Python »æÖÆ Vijay¡¹
from sketchpy import library
myObject = library.vijay()
myObject.draw()
7. FTFY
FTFYÊÇÒ»¸öPython¿â£¬ËüµÄÈ«³ÆÊÇ"Fixes Text For You"£¬ÓÃÓÚÐÞ¸´ºÍ¾ÀÕýÎı¾Öеij£¼û±àÂëÎÊÌâºÍUnicode×Ö·ûÎÊÌâ¡£Ëü¿ÉÒÔ×Ô¶¯¼ì²âºÍÐÞ¸´¸÷ÖÖ±àÂëÎÊÌ⣬ʹµÃÎı¾ÔÚ´¦ÀíºÍÏÔʾʱ¸ü¼Ó׼ȷºÍÒ»Ö¡£
¡¸°²×°FTFY¡¹
pip install ftfy
¡¸Ê¾Àý¡¹
print(ftfy.fix_text('Correct the sentence using a€?ftfya€\x9d.'))
print(ftfy.fix_text('a?¡± No problems with text'))
print(ftfy.fix_text('? perturber la r??flexion'))
¡¸Êä³ö¡¹
¼ÓºÃÓÑ 
·¢¶ÌÐÅ
¹ÜÀíÔ±
Post By£º2023/9/20 13:55:15 [Ö»¿´¸Ã×÷Õß]
