3.2. Numeric Float

  • Represents floating point number (vide IEEE-754)

  • Could be both signed and unsigned

  • Default float size is 64 bit

  • Python automatically extends float when need bigger number

>>> data = 1.337
>>> data = +1.337
>>> data = -1.337

3.2.1. Without Zero Notation

  • .44 - notation without leading zero

  • 69. - notation without trailing zero

  • Used by numpy

Leading zero:

>>> data = .44
>>> print(data)
0.44

Trailing zero:

>>> data = 69.
>>> print(data)
69.0

3.2.2. Engineering Notation

  • The exponential is a number divisible by 3

  • Allows the numbers to explicitly match their corresponding SI prefixes

  • The E (or e) should not be confused with the exponential e which holds a completely different significance

Table 3.1. Engineering notation

Name

Symbol

Base

Value

yotta

Y

1e24

1000000000000000000000000.0

zetta

Z

1e21

1000000000000000000000.0

exa

E

1e18

1000000000000000000.0

peta

P

1e15

1000000000000000.0

tera

T

1e12

1000000000000.0

giga

G

1e9

1000000000.0

mega

M

1e6

1000000.0

kilo

k

1e3

1000.0

1e0

1.0

milli

m

1e−3

0.001.0

micro

μ

1e−6

0.000001.0

nano

n

1e−9

0.000000001.0

pico

p

1e−12

0.000000000001.0

femto

f

1e−15

0.000000000000001.0

atto

a

1e−18

0.000000000000000001.0

zepto

z

1e−21

0.000000000000000000001.0

yocto

y

1e−24

0.000000000000000000000001.0

>>> x = 1e6
>>> print(x)
1000000.0
>>>
>>> x = 1E6
>>> print(x)
1000000.0
>>> x = +1e6
>>> print(x)
1000000.0
>>>
>>> x = -1e6
>>> print(x)
-1000000.0
>>> x = 1e-3
>>> print(x)
0.001
>>>
>>> x = 1e-6
>>> print(x)
1e-06

3.2.3. Scientific notation

  • The E (or e) should not be confused with the exponential e which holds a completely different significance

>>> 1e1
10.0
>>>
>>> 1e2
100.0
>>>
>>> 1e3
1000.0
>>> 1e-3
0.001
>>>
>>> 1e-4
0.0001
>>>
>>> 1e-5
1e-05
>>>
>>> 1e-6
1e-06
>>> 1e3
1000.0
>>>
>>> -1e3
-1000.0
>>>
>>> 1e-3
0.001
>>>
>>> -1e-3
-0.001
>>> 1.337 * 1e3
1337.0
>>>
>>> 1.337 * 1e-3
0.001337

3.2.4. Type Casting

Builtin function float() converts argument to float

>>> float(1)
1.0
>>>
>>> float(+1)
1.0
>>>
>>> float(-1)
-1.0
>>> float(1.337)
1.337
>>>
>>> float(+1.337)
1.337
>>>
>>> float(-1.337)
-1.337
>>> float('1.337')
1.337
>>>
>>> float('+1.337')
1.337
>>>
>>> float('-1.337')
-1.337
>>> float('1,337')
Traceback (most recent call last):
ValueError: could not convert string to float: '1,337'
>>> float('+1,337')
Traceback (most recent call last):
ValueError: could not convert string to float: '+1,337'
>>> float('-1,337')
Traceback (most recent call last):
ValueError: could not convert string to float: '-1,337'

3.2.5. Round Number

Rounding a number

>>> pi = 3.14159265359
>>>
>>>
>>> round(pi, 4)
3.1416
>>>
>>> round(pi, 2)
3.14
>>>
>>> round(pi)
3
>>>
>>> round(pi, 0)
3.0

Rounding a number in string formatting

>>> pi = 3.14159265359
>>>
>>>
>>> print(f'Pi number is {pi}')
Pi number is 3.14159265359
>>>
>>> print(f'Pi number is {pi:f}')
Pi number is 3.141593
>>>
>>> print(f'Pi number is {pi:.4f}')
Pi number is 3.1416
>>>
>>> print(f'Pi number is {pi:.2f}')
Pi number is 3.14
>>>
>>> print(f'Pi number is {pi:.0f}')
Pi number is 3
>>> round(10.5)
10
>>>
>>> round(10.51)
11

3.2.6. Type Checking

>>> x = 1.2
>>>
>>> type(x)
<class 'float'>
>>>
>>> x = 1.2
>>> type(x) is float
True
>>>
>>> type(x) in (int, float)
True
>>> x = 1.2
>>>
>>> isinstance(x, float)
True
>>>
>>> isinstance(x, (int,float))
True
>>>
>>> isinstance(x, int|float)  # since 3.10
True

3.2.7. Built-in Functions

Builtin function pow() raises number to the n-th power. Note, that arithmetic operator ** also raises number to the power:

>>> pow(10, 2)
100
>>>
>>> pow(2, -1)
0.5
>>> pow(1.337, 3)
2.389979753
>>>
>>> pow(4, 0.5)
2.0
>>>
>>> pow(2, 0.5)
1.4142135623730951

Builtin function pow() can be used to calculate roots of a number:

>>> pow(4, 1/2)
2.0
>>>
>>> pow(2, 1/2)
1.4142135623730951
>>>
>>> pow(27, 1/3)
3.0
>>> pow(4, -1/2)
0.5
>>>
>>> pow(2, -1/2)
0.7071067811865476
>>>
>>> pow(27, -1/3)
0.33333333333333337
>>> pow(-2, -1)
-0.5
>>>
>>> pow(-4, -1)
-0.25

Builtin function pow() can return complex numbers. Note that Python has special complex() numeric type.

>>> pow(-2, -1/2)
(4.329780281177467e-17-0.7071067811865476j)
>>>
>>> pow(-2, 1/2)
(8.659560562354934e-17+1.4142135623730951j)
>>>
>>> pow(-4, -1/2)
(3.061616997868383e-17-0.5j)
>>>
>>> pow(-4, 1/2)
(1.2246467991473532e-16+2j)

Absolute value

>>> abs(1)
1
>>>
>>> abs(1.337)
1.337
>>> abs(-1)
1
>>>
>>> abs(-1.337)
1.337

3.2.8. Assignments

Code 3.9. Solution
"""
* Assignment: Type Float Tax
* Required: yes
* Complexity: easy
* Lines of code: 5 lines
* Time: 3 min

English:
    1. Cost of the service is 100.00 PLN net
    2. Service has value added tax (VAT) rate of 23%
    3. Calculate tax and gross values
    4. To calculate tax, multiply net times VAT
    5. To calculate gross multiply net times VAT plus 1
    6. Result must be in PLN
    7. Mind the operator precedence
    8. Run doctests - all must succeed

Polish:
    1. Cena usługi wynosi 100.00 PLN netto
    2. Usługa objęta jest 23% stawką VAT
    3. Oblicz wartości podatku oraz cenę brutto
    4. Aby obliczyć podatek, pomnóż cenę netto razy stawkę VAT
    5. Aby obliczyć cenę brutto pomnóż cenę netto razy stawka VAT plus 1
    6. Wynik musi być w PLN
    7. Zwróć uwagę na kolejność wykonywania działań
    8. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert net is not Ellipsis, \
    'Assign your result to variable `net`'
    >>> assert tax is not Ellipsis, \
    'Assign your result to variable `tax`'
    >>> assert gross is not Ellipsis, \
    'Assign your result to variable `gross`'
    >>> assert type(net) is float, \
    'Variable `net` has invalid type, should be float'
    >>> assert type(tax) is float, \
    'Variable `tax` has invalid type, should be float'
    >>> assert type(gross) is float, \
    'Variable `gross` has invalid type, should be float'

    >>> net / PLN
    100.0
    >>> tax / PLN
    23.0
    >>> gross / PLN
    123.0
"""

PLN = 1
VAT_23 = 23 / 100

# 100.0 PLN, without tax
# type: float
net = ...

# 23% of net
# type: float
tax = ...

# Gross is net plus tax in PLN
# type: float
gross = ...


Code 3.10. Solution
"""
* Assignment: Type Float Altitude
* Required: yes
* Complexity: easy
* Lines of code: 3 lines
* Time: 3 min

English:
    1. Plane altitude is 10.000 ft
    2. Data uses imperial (US) system
    3. Convert to metric (SI) system
    4. Result round to one decimal place
    5. Run doctests - all must succeed

Polish:
    1. Wysokość lotu samolotem wynosi 10 000 ft
    2. Dane używają systemu imperialnego (US)
    3. Przelicz je na system metryczny (układ SI)
    4. Wynik zaokrąglij do jednego miejsca po przecinku
    5. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert altitude is not Ellipsis, \
    'Assign your result to variable `altitude`'
    >>> assert altitude_m is not Ellipsis, \
    'Assign your result to variable `altitude_m`'
    >>> assert altitude_ft is not Ellipsis, \
    'Assign your result to variable `altitude_ft`'
    >>> assert type(altitude) is float, \
    'Variable `altitude` has invalid type, should be float'
    >>> assert type(altitude_m) is float, \
    'Variable `altitude_m` has invalid type, should be float'
    >>> assert type(altitude_ft) is float, \
    'Variable `altitude_ft` has invalid type, should be float'

    >>> altitude
    3048.0
    >>> altitude_m
    3048.0
    >>> altitude_ft
    10000.0
"""

m = 1
ft = 0.3048 * m

# 10_000 ft
# type: float
altitude = ...

# Altitude in meters
# type: float
altitude_m = ...

# Altitude in feet
# type: float
altitude_ft = ...

Code 3.11. Solution
"""
* Assignment: Type Float Volume
* Required: yes
* Complexity: easy
* Lines of code: 4 lines
* Time: 3 min

English:
    1. Bottle volume is 20 Fl Oz
    2. Data uses imperial (US) system
    3. Convert to metric (SI) system
    4. Run doctests - all must succeed

Polish:
    1. Objętość butelki wynosi 20 Fl Oz
    2. Dane używają systemu imperialnego (US)
    3. Przelicz je na system metryczny (układ SI)
    4. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert volume is not Ellipsis, \
    'Assign your result to variable `volume`'
    >>> assert volume_floz is not Ellipsis, \
    'Assign your result to variable `volume_floz`'
    >>> assert volume_l is not Ellipsis, \
    'Assign your result to variable `volume_l`'
    >>> assert type(volume) is float, \
    'Variable `volume` has invalid type, should be float'
    >>> assert type(volume_floz) is float, \
    'Variable `volume_floz` has invalid type, should be float'
    >>> assert type(volume_l) is float, \
    'Variable `volume_l` has invalid type, should be float'

    >>> volume_floz
    20.0
    >>> volume_l
    0.5914688
"""

liter = 1
floz = 0.02957344 * liter

# 20 Fl Oz
# type: float
volume = ...

# Volume in fluid ounces
# type: float
volume_floz = ...

# Volume in liters
# type: float
volume_l = ...

Code 3.12. Solution
"""
* Assignment: Type Float Euler
* Required: yes
* Complexity: easy
* Lines of code: 4 lines
* Time: 5 min

English:
    1. Euler's number is 2.71828
    2. Round number using f-string formatting
    3. Run doctests - all must succeed

Polish:
    1. Liczba Eulra to 2.71828
    2. Zaokrąglij liczbę wykorzystując formatowanie f-string
    3. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert a is not Ellipsis, \
    'Assign your result to variable `a`'
    >>> assert b is not Ellipsis, \
    'Assign your result to variable `b`'
    >>> assert c is not Ellipsis, \
    'Assign your result to variable `c`'
    >>> assert d is not Ellipsis, \
    'Assign your result to variable `d`'
    >>> assert type(a) is str, \
    'Variable `a` has invalid type, should be str'
    >>> assert type(b) is str, \
    'Variable `b` has invalid type, should be str'
    >>> assert type(c) is str, \
    'Variable `c` has invalid type, should be str'
    >>> assert type(d) is str, \
    'Variable `d` has invalid type, should be str'

    >>> a
    "Euler's number with 0 decimal places: 3"
    >>> b
    "Euler's number with 1 decimal places: 2.7"
    >>> c
    "Euler's number with 2 decimal places: 2.72"
    >>> d
    "Euler's number with 3 decimal places: 2.718"
"""

EULER = 2.71828

# Euler's number with 0 decimal places
# type: str
a = f"Euler's number with 0 decimal places: {EULER}"

# Euler's number with 1 decimal places
# type: str
b = f"Euler's number with 1 decimal places: {EULER}"

# Euler's number with 2 decimal places
# type: str
c = f"Euler's number with 2 decimal places: {EULER}"

# Euler's number with 3 decimal places
# type: str
d = f"Euler's number with 3 decimal places: {EULER}"

Code 3.13. Solution
"""
* Assignment: Type Float Velocity
* Required: yes
* Complexity: easy
* Lines of code: 9 lines
* Time: 3 min

English:
    1. Speed limit is 75 MPH
    2. Data uses imperial (US) system
    3. Convert to metric (SI) system
    4. Speed limit print in KPH (km/h)
    5. Run doctests - all must succeed

Polish:
    1. Ograniczenie prędkości wynosi 75 MPH
    2. Dane używają systemu imperialnego (US)
    3. Przelicz je na system metryczny (układ SI)
    4. Ograniczenie prędkości wypisz w KPH (km/h)
    5. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert kph is not Ellipsis, \
    'Assign your result to variable `kph`'
    >>> assert mph is not Ellipsis, \
    'Assign your result to variable `mph`'
    >>> assert speed_limit_mph is not Ellipsis, \
    'Assign your result to variable `speed_limit_mph`'
    >>> assert speed_limit_kph is not Ellipsis, \
    'Assign your result to variable `speed_limit_kph`'
    >>> assert type(kph) is float, \
    'Variable `kph` has invalid type, should be float'
    >>> assert type(mph) is float, \
    'Variable `mph` has invalid type, should be float'
    >>> assert type(speed_limit_mph) is float, \
    'Variable `speed_limit_mph` has invalid type, should be float'
    >>> assert type(speed_limit_kph) is float, \
    'Variable `speed_limit_kph` has invalid type, should be float'

    >>> round(kph, 3)
    0.278
    >>> round(mph, 3)
    0.447
    >>> round(speed_limit_mph, 1)
    75.0
    >>> round(speed_limit_kph, 1)
    120.7
"""

SECOND = 1
MINUTE = 60 * SECOND
HOUR = 60 * MINUTE

m = 1
km = 1000 * m
mi = 1609.344 * m

# Miles per hour
# type: float
mph = ...

# Kilometers per hour
# type: float
kph = ...

# 75 miles per hour
# type: float
speed_limit = ...

# Speed limit in miles per hour
# type: float
speed_limit_mph = ...

# Speed limit in kilometers per hour
# type: float
speed_limit_kph = ...

3.2.9. Homework

Code 3.14. Solution
"""
* Assignment: Type Float Pressure
* Required: no
* Complexity: medium
* Lines of code: 2 lines
* Time: 3 min

English:
    1. Operational pressure of EMU spacesuit: 4.3 PSI
    2. Operational pressure of ORLAN spacesuit: 40 kPa
    3. Calculate operational pressure in hPa for EMU
    4. Calculate operational pressure in hPa for Orlan
    5. Run doctests - all must succeed

Polish:
    1. Ciśnienie operacyjne skafandra kosmicznego EMU (NASA): 4.3 PSI
    2. Ciśnienie operacyjne skafandra kosmicznego ORLAN (Roscosmos): 40 kPa
    3. Oblicz ciśnienie operacyjne skafandra EMU w hPa
    4. Oblicz ciśnienie operacyjne skafandra Orlan w hPa
    5. Uruchom doctesty - wszystkie muszą się powieść

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert emu is not Ellipsis, \
    'Assign your result to variable `emu`'
    >>> assert orlan is not Ellipsis, \
    'Assign your result to variable `orlan`'
    >>> assert type(emu) is float, \
    'Variable `emu` has invalid type, should be float'
    >>> assert type(orlan) is float, \
    'Variable `orlan` has invalid type, should be float'

    >>> round(orlan, 1)
    400.0
    >>> round(emu, 1)
    296.5
"""

Pa = 1
hPa = 100 * Pa
kPa = 1000 * Pa
psi = 6894.757 * Pa

# 4.3 pounds per square inch in hectopascals, round to one decimal place
# type: float
emu = ...

# 40 kilopascals in hectopascals, round to one decimal place
# type: float
orlan = ...

../../_images/spacesuits.png

Figure 3.1. EMU and Orlan

Code 3.15. Solution
"""
* Assignment: Type Float Percent
* Required: no
* Complexity: medium
* Lines of code: 2 lines
* Time: 3 min

English:
    1. International Standard Atmosphere (ISA) at sea level is
       1 ata = 1013.25 hPa
    2. Calculate `pO2` - partial pressure of Oxygen at sea level in hPa
    3. To calculate partial pressure use ratio
       (100% is 1013.25 hPa, 20.946% is how many hPa?)
    4. Run doctests - all must succeed

Polish:
    1. Międzynarodowa standardowa atmosfera (ISA) na poziomie morza wynosi
       1 ata = 1013.25 hPa
    2. Oblicz `pO2` - ciśnienie parcjalne tlenu na poziomie morza w hPa
    3. Aby policzyć ciśnienie parcjalne skorzystaj z proporcji
       (100% to 1013.25 hPa, 20.946% to ile hPa?)
    4. Uruchom doctesty - wszystkie muszą się powieść

Hints:
    * 1 hPa = 100 Pa
    * 1 kPa = 1000 Pa
    * 1 ata = 1013.25 hPa (ISA - International Standard Atmosphere)
    * Atmosphere gas composition:

        * Nitrogen 78.084%
        * Oxygen 20.946%
        * Argon 0.9340%
        * Carbon Dioxide 0.0407%
        * Others 0.001%

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert pO2 is not Ellipsis, \
    'Assign your result to variable `pO2`'
    >>> assert type(pO2) is float, \
    'Variable `pO2` has invalid type, should be float'

    >>> ata
    101325.0
    >>> round(pO2, 1)
    212.2
"""

PERCENT = 100
N2 = 78.084 / PERCENT
O2 = 20.946 / PERCENT
Ar = 0.9340 / PERCENT
CO2 = 0.0407 / PERCENT
Others = 0.001 / PERCENT

Pa = 1
hPa = 100 * Pa
kPa = 1000 * Pa

# Standard atmosphere (ATA) is pressure at sea level: 1013.25 hectopascals
# type: float
ata = ...

# 20.946% of pressure at sea level in hPa, round to one decimal place
# type: float
pO2 = ...

Code 3.16. Solution
"""
* Assignment: Type Float Gradient
* Required: no
* Complexity: hard
* Lines of code: 7 lines
* Time: 8 min

English:
    1. At what altitude above sea level, pressure is equal
       to partial pressure of Oxygen
    2. Print result in meters rounding to two decimal places
    3. To calculate partial pressure use ratio
       (100% is 1013.25 hPa, 20.946% is how many hPa?)
    4. Calculated altitude is pressure at sea level minus
       oxygen partial pressure divided by gradient
    5. Mind the operator precedence
    6. Run doctests - all must succeed

Polish:
    1. Na jakiej wysokości nad poziomem morza panuje ciśnienie
       równe ciśnieniu parcjalnemu tlenu?
    2. Wypisz rezultat w metrach zaokrąglając do dwóch miejsc po przecinku
    3. Aby policzyć ciśnienie parcjalne skorzystaj z proporcji
       (100% to 1013.25 hPa, 20.946% to ile hPa?)
    4. Wyliczona wysokość to ciśnienie atmosferyczne na poziomie morza minus
       ciśnienie parcjalne tlenu podzielone przez gradient
    5. Zwróć uwagę na kolejność wykonywania działań
    6. Uruchom doctesty - wszystkie muszą się powieść

Hints:
    * pressure gradient (decrease) = 11.3 Pa / 1 m
    * 1 hPa = 100 Pa
    * 1 kPa = 1000 Pa
    * 1 ata = 1013.25 hPa (ISA - International Standard Atmosphere)
    * Atmosphere gas composition:

        * Nitrogen 78.084%
        * Oxygen 20.946%
        * Argon 0.9340%
        * Carbon Dioxide 0.0407%
        * Others 0.001%

Tests:
    >>> import sys; sys.tracebacklimit = 0

    >>> assert pO2 is not Ellipsis, \
    'Assign your result to variable `pO2`'
    >>> assert gradient is not Ellipsis, \
    'Assign your result to variable `gradient`'
    >>> assert altitude is not Ellipsis, \
    'Assign your result to variable `altitude`'
    >>> assert type(pO2) is float, \
    'Variable `pO2` has invalid type, should be float'
    >>> assert type(gradient) is float, \
    'Variable `gradient` has invalid type, should be float'
    >>> assert type(altitude) is float, \
    'Variable `altitude` has invalid type, should be float'

    >>> pO2
    21223.5345
    >>> gradient
    11.3
    >>> round(altitude/m, 2)
    7088.63
"""

PERCENT = 100
N2 = 78.084 / PERCENT
O2 = 20.946 / PERCENT
Ar = 0.9340 / PERCENT
CO2 = 0.0407 / PERCENT
Others = 0.001 / PERCENT

m = 1
Pa = 1
hPa = 100 * Pa
ata = 1013.25 * hPa
pO2 = O2 * ata

# 11.3 Pascals per meter
# type: float
gradient = ...

# Altitude is ata minus pO2 all that divided by gradient
# type: float
altitude = ...