Python 3.6.9 : My colab tutorials - part 014.

Here we come to the 16th notebook created with the colab utility from Google.

In this notebook, I will show you how you can view a dataset of images.

See the next image with a few of the shapes of the dataset:

You can find the full source code on my GitHub account.

Python 3.6.9 : My colab tutorials - part 013.

In this tutorial created with the online tool google colab, we exemplified again how to access the IMDB dataset, which contains from the index point of view and what is the correspondence with the IMDB reviews, as well as how to work and create several sets of data for trains and what is the difference between them.

You can see the source code in python on this notebook.

Python 3.6.9 : My colab tutorials - part 012.

The purpose of this tutorial is to show the IMDB review dataset.

You can find the source code on my GitHub account here.

Python 3.6.9 : My colab tutorials - part 011.

The purpose of this tutorial is to use the google TPU device together with Keras.

You need to set from the Edit menu and set for the notebook the device called TPU.

You can find the source code on my GitHub account here.

Python 3.9.1 : ABC - Abstract Base Classes - part 001.

Abstract classes are classes that contain one or more abstract methods.

By default, Python does not provide abstract classes.

Python comes with a module that provides the base for defining Abstract Base Classes (named ABC).

An abstract class can be considered as a blueprint for other classes.

By defining an abstract base class, you can define a common API for a set of subclasses.

A class that is derived from an abstract class cannot be instantiated unless all of its abstract methods are overridden.

[mythcat@desk ~]$ python3.9
Python 3.9.5 (default, May  4 2021, 00:00:00) 
[GCC 10.3.1 20210422 (Red Hat 10.3.1-1)] on linux
Type "help", "copyright", "credits" or "license" for more information.
>>> from abc import ABC
>>> class Test_ABC(ABC):
...     pass
... 
>>> Test_ABC.register(tuple)

>>> assert issubclass(tuple,Test_ABC)
>>> assert isinstance((), Test_ABC)
>>> class Foo:
...     def __getitem__(self, index):
...         ...
...     def __len__(self):
...         ...
...     def get_iterator(self):
...         return iter(self)
... 
>>> Test_ABC.register(Foo)
...

Let's see an example:

from abc import ABC, abstractmethod
 
class Vehicle(ABC):
    @abstractmethod
    def action(self):
        pass

class Air(Vehicle):
    # overriding abstract method
    def action(self):
        print("this flies in the air")
 
class Ground(Vehicle):
    # overriding abstract method
    def action(self):
        print("this running on the field")

class Civil(Ground):
    def action(self):
        print("Civil class - running on the field")

# Can't instantiate abstract class with abstract method action, don't use it
# abc = Vehicle()

abc = Air()
abc.action()

abc = Ground()
abc.action()

abc = Civil()
abc.action()

print( issubclass(Civil, Vehicle))
print( isinstance(Civil(), Vehicle))

This is the result:

[mythcat@desk PythonProjects]$ python3.9 ABC_001.py 
this flies in the air
this running on the field
Civil class - running on the field
True
True

Python 2.7.18 : Kick Start Google - Boring Numbers.

Today I solved one of the problems required for solving Google Kick Start in 2020, see on my account.

Round H 2020 - Kick Start 2020 Boring Numbers (7pts, 12pts) Problem Ron read a book about boring numbers. According to the book, a positive number is called boring if all of the digits at even positions in the number are even and all of the digits at odd positions are odd. The digits are enumerated from left to right starting from 1. For example, the number 1478 is boring as the odd positions include the digits {1, 7} which are odd and even positions include the digits {4, 8} which are even. Given two numbers L and R, Ron wants to count how many numbers in the range [L, R] (L and R inclusive) are boring. Ron is unable to solve the problem, hence he needs your help.

Let's try to find the solution:

import math
print("Round H 2020 - Kick Start 2020: Detect is positive number is called boring.\n")
nr = int(input("get natural positive number: "))

all_cond = []
# detect if the number is odd or even number
def detect_odd_even(num):
  if (num % 2) == 0:  
    #print("{0} is Even number".format(num)) 
    detect = True  
  else:  
    #print("{0} is Odd number".format(num))  
    detect = False
  return detect
# check if is an boring number.
def boring_number(num):
    for p,num in enumerate(str(num),1):
        print(p,num)
        if (detect_odd_even(p) == detect_odd_even(int(num))): all_cond.append(True)
        else:
          all_cond.append(False)

# check the number is 
boring_number(nr)
# print result if the positive number is boring
if (all(all_cond) == True): print("{0} is an positive boring number".format(nr))
else:
  print("{0} is not a positive boring number".format(nr))

Let's test it:

~/mathissues$ python math_003.py 
Round H 2020 - Kick Start 2020: Detect is positive number is called boring.

get natural positive number: 345
(1, '3')
(2, '4')
(3, '5')
345 is an positive boring number

Then la last step is to test any number from range of given two numbers L and R.

The new source code is this:

import math
print("Round H 2020 - Kick Start 2020: Detect is positive number is called boring.\n")
#nr = int(input("get natural positive number: "))

all_cond = []
# detect if the number is odd or even number
def detect_odd_even(num):
  if (num % 2) == 0:  
    #print("{0} is Even number".format(num)) 
    detect = True  
  else:  
    #print("{0} is Odd number".format(num))  
    detect = False
  return detect
# check if is an boring number.
def boring_number(num):
    for p,num in enumerate(str(num),1):
        print(p,num)
        if (detect_odd_even(p) == detect_odd_even(int(num))): all_cond.append(True)
        else:
          all_cond.append(False)

# check the number is 
#boring_number(nr)
# print result if the positive number is boring

nr1 = int(input("get firt natural positive number: "))
nr2 = int(input("get firt natural positive number: "))
if nr1 < nr2:
  n1 = nr1
  n2 = nr2
else: 
  n1 = nr2
  n2 = nr1
for all_nr in range(n1,n2):
  all_cond = []
  boring_number(all_nr)
  print(all_nr)
# print result if the positive number is boring
  if (all(all_cond) == True): print("{0} is an positive boring number".format(all_nr))
  else: print("{0} is not a positive boring number".format(all_nr))
  all_cond = [] 

The final solution result to test all numbers in range given two numbers L and R can be see bellow:

~/mathissues$ python math_003.py 
Round H 2020 - Kick Start 2020: Detect is positive number is called boring.

get firt natural positive number: 11
get firt natural positive number: 16
(1, '1')
(2, '1')
11
11 is not a positive boring number
(1, '1')
(2, '2')
12
12 is an positive boring number
(1, '1')
(2, '3')
13
13 is not a positive boring number
(1, '1')
(2, '4')
14
14 is an positive boring number
(1, '1')
(2, '5')
15
15 is not a positive boring number

Python 3.9.1 : Python and Spectator Earth.

The Spectator Earth allows you to track satellites, access their imagery, and easily build new information, based on data from this amazing orbital infrastructure.

You need just an API KEY to use it with cURL, Python, or JavaScript. 

In this tutorial, I will show you how can be used.

Login on the app.spectator.earth and get your API Key. 

Let's see some simple examples.

This first example shows you the satellite by id:

import requests

id = input("Type id sattelite: ")
satellite_id = id
url = 'https://api.spectator.earth/satellite/{satellite_id}'.format(satellite_id=satellite_id)

response = requests.get(url)
data = response.json()
print(data)

Let's see some satellite by ids:

[mythcat@desk Spectator]$ python  satellite_all.py 
Type id sattelite: 1
{'id': 1, 'type': 'Feature', 'geometry': {'type': 'Point', 'coordinates': [-51.88851761326367, 
70.75978200389422]}, 'properties': {'name': 'Sentinel-1A', 'norad_id': 39634, 'sensors': 
[{'type': 'SAR', 'avg_footprint_width': '3.20'}], 'open': True, 'platform': 'Sentinel-1A'}}
[mythcat@desk Spectator]$ python  satellite_all.py 
Type id sattelite: 2
{'id': 2, 'type': 'Feature', 'geometry': {'type': 'Point', 'coordinates': [42.046601163641796, 
-14.660442921557335]}, 'properties': {'name': 'Sentinel-2A', 'norad_id': 40697, 'sensors': 
[{'type': 'OPTICAL', 'avg_footprint_width': '2.32'}], 'open': True, 'platform': 'Sentinel-2A'}}
[mythcat@desk Spectator]$ python  satellite_all.py 
Type id sattelite: 3
{'id': 3, 'type': 'Feature', 'geometry': {'type': 'Point', 'coordinates': [-91.98478583784988, 
79.45732380441011]}, 'properties': {'name': 'Sentinel-3A', 'norad_id': 41335, 'sensors': 
[{'type': 'OPTICAL', 'avg_footprint_width': '10.16'}, {'type': 'OPTICAL', 
'avg_footprint_width': '11.20'}], 'open': True, 'platform': 'Sentinel-3A'}}
[mythcat@desk Spectator]$ python  satellite_all.py 
Type id sattelite: 4

Let's see one example with satellite overpasses:

import requests
import json
api_key = input("api_key :")
bbox = '19.59,49.90,20.33,50.21'
satellites = 'Sentinel-2A,Sentinel-2B'
url = 'https://api.spectator.earth/overpass/?api_key={api_key}&bbox={bbox}&
satellites={satellites}'.format(api_key=api_key, bbox=bbox, satellites=satellites)
response = requests.get(url)
data = response.json()
print(type(data))
print(data)

You can query for overpasses of the chosen satellite over a defined area of interest and the output provides you with a satellite sensor footprint for the nearest overpass, overpass frequency in seconds, and all information available.

Query parameters for the URL variable are:

The result is this:

[mythcat@desk Spectator]$ python satellite.py 
api_key :....
...
{'frequency': 93996, 'overpasses': [{'id': 16486437, 'acquisition': True, 'date': 
'2021-02-26T09:57:00Z', 'footprint': {'type': 'Polygon', 'coordinates': 
...
footprint': {'type': 'Polygon', 'coordinates': 
...
[[[19.153675312697636, 46.847554078717884], ... 

Query parameters for the url :

• api_key - your API key
• bbox - area of interest bounding box list of coords (lon, lat, lon, lat);
• satellites - which satellites to include like: (Sentinel-1A, Sentinel-1A, Sentinel-2A, Sentinel-2B, Sentinel-3A, Landsat-8) - optional;
• days_before - a number of days before the current date for which overpasses should be computed integer optional, default=0;
• days_after - a number of days after the current date for which overpasses should be computed integer optional, default=7;

You can see a image get from my location:

Python 3.6.0 : Django 3.2 alpha 1 released.

Django is a high-level Python Web framework that encourages rapid development and clean, pragmatic design. Built by experienced developers, it takes care of much of the hassle of Web development, so you can focus on writing your app without needing to reinvent the wheel. It’s free and open source. 

I tested it and I was satisfied with the way it works with this framework and it has many good features for the web. 

Django 3.2 is designated as a long-term support release.

Today, Django 3.2 alpha 1 is available with new features.

A good roadmap towards Django 3.2. can be found on this schedule webpage.

As with all alpha and beta packages, this is not for production use.

Django 3.2 supports Python 3.6, 3.7, 3.8, and 3.9. The next release is expected in April 2021, see:

• January 14, 2021, Django 3.2 alpha; feature freeze;
• February 18 Django 3.2 beta; non-release blocking bug fix freeze;
• March 18 Django 3.2 RC 1; translation string freeze;
• April 6 Django 3.2 final release.