Difference between revisions of "Units"

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| 1000USD || INR || 66808.20948336872INR  
 
| 1000USD || INR || 66808.20948336872INR  
 
|}
 
|}
 +
 +
 +
We can override internal conversion rates by using SETCONVERSION.
 +
 +
SETCONVERSION(1<>euro,1<>dollar,1.1)
 +
 +
PRINTCONVERSION();
 +
 +
can give the recently set conversion rates.
 +
 +
1<>€<>$
 +
 +
gives 1 euro to convert to 1$.
 +
 +
SETCONVERSION(1$,1€,0.9);
 +
 +
shows the following on PRINTCONVERSION():
 +
{
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  dollar:euro: 0.9,
 +
  euro:dollar: 1.1111111111111112
 +
}
 +
  
  
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(1..10)<>kg
 
(1..10)<>kg
 
 
b<>$;
 
 
SETCONVERSION(1<>euro,1<>dollar,1.1)
 
 
 
SETCONVERSION(1$,1€,0.9);
 
PRINTCONVERSION();
 
345$<>€
 
 
 
 
1$<>1₹ // without conversion will fail.
 
1$<>1₹ // without conversion will fail.

Revision as of 13:23, 13 June 2016

How to specify units

Units are a unique, inherent and simple feature of the z^3 language.

Using units is simple and easy. For example:

a=1m;

indicates that a is now a variable containing the value of 1 meter. For more complex units we can enclose them in brackets as in 3(m/sec).

If a variable needs to be specified in specific units, simply use the <> operator. Such as: a<>(m/sec);

In z^3 language, <> is the unit conversion operator. Also, any arithmetic operator such as +, -, *, /, ^, % etc. should be enclosed within < and > to allow unit conversions to propagate through these operations. These conversion operations can be done on arrays as parameters also. Hence to add a meter to 2 centimeters, do the following: a=1m<+>2cm; and z^3 will give the answer: 102 cm.

Note, that this result now carries the units with it for further operations. For example: a=(1m<+>2cm)<^>3; gives the answer as 1061208 cm3.

To convert the current value of a variable to a different unit, simply use the <> operator: a<>cm;

Notice that if a already had a unit, it will be appropriately converted using the units. If it did not have units inherently, it will simply be given the units. $> a=1 1 $> a<>cm; 1 cm.

$> a=1m; 1 m. $> a<>cm; 100 cm.

In the second case, 1m is converted to 100cm.

Unit Prefixes

Similarly, scales such as milli, mega, etc. are supported using conventional SI units. a=1m; 1 m. a<>ym; 1.0000000000000001e+24 ym.

Here a now has the unit yoctometer.

Using uppercase Y, we get the answer in Yottameter. a=1m; 1 m. a<>Ym; 1.0000000000000001e-24 Ym.

These conversions of scale follow the SI unit prefix standards.

Metricscales.png

Conversion among Unit Systems

z^3 supports conversion among unit systems, such as SI Units and FPS systems.

For example:

a=1mi; 1 mi.

a<>km; 1.6093439999999999 km.

Notice that the mi (miles) unit of variable a is converted to km.

Units on Array of Values

Units work on variables as simple numerical values or as arrays.

Let us consider numbers 1 to 100.

a=1..100;

Then say this is in miles.

b=a<>(mi);

Convert to kilometers.

b<>km

Numeric Units UNITSOF
1mi km 1.6093439999999999km
2mi km 3.2186879999999998km
3mi km 4.828031999999999km
4mi km 6.4373759999999995km
5mi km 8.046719999999999km
6mi km 9.656063999999999km
7mi km 11.265407999999999km
8mi km 12.874751999999999km
9mi km 14.484096km
10mi km 16.093439999999998km

We can convert arrays of Unit values to converted values as in the following:

a=(1..100)<>℃; b=a<>℉;


Numeric Units UNITSOF
1℃ degF 33.8℉
2℃ degF 35.6℉
3℃ degF 37.4℉
4℃ degF 39.2℉
5℃ degF 41℉
6℃ degF 42.8℉
7℃ degF 44.6℉
8℃ degF 46.4℉
9℃ degF 48.2℉
10℃ degF 50℉


Units inside functions

Units can be highly effective inside functions. These, along with constants, provide a fantastic way to express your logic beautifully.

Let us consider how we can write E=mc^2. E:=(m<>kg)<*>(SPEEDOFLIGHT()<^>2);

E(2kg)

gives: 179751035747363520kg.m2.s-2

Note the use of <*> and <^> for the operators in unit operations.

In case you wanted to give the output in Joules.

E(2kg)<>J

gives: 179751035747363520J


Let us add variables intermixing miles and kilometer.

a=1mi;

b=10km;

[a,b,(a<+>b)<>mi]

[a,b,(a<+>b)<>mi]

1mi 10km 7.21371192237334mi

10mi<>km

can convert miles to kilometers.


Units Aware Internal Functions

In most sytems, functions like SIN operate on radians. Most users are unaware of this, and get confused when they get SIN(90) to be something unexpected.

With z^3 unit aware functions, this is not an issue.

For example,

a=90deg; SIN(a)

will automatically convert the variable a into radians before calculations. To see the difference, try SIN(90) vs. SIN(90<>deg).

The answers given are: 0.8939966636005579 and 1.

Unit awareness is built into functions in z^3. (Note: Some functions are being transitioned).

Generation of Arrays with Units

rad2piby10

0㎭
0.6283185307179586㎭
1.2566370614359172㎭
1.8849555921538759㎭
2.5132741228718345㎭
3.141592653589793㎭
3.7699111843077517㎭
4.39822971502571㎭
5.026548245743669㎭
5.654866776461628㎭
6.283185307179586㎭

Note the results from rad2piby10 is automatically in radians.

Similarly array results using series in degrees are also marked with units of degrees.

deg110by10

10°
20°
30°
40°
50°
60°
70°
80°
90°
100°
110°

(rad2piby10)<>rad<>deg

Numeric Units UNITSOF
0㎭ deg
0.6283185307179586㎭ deg 36°
1.2566370614359172㎭ deg 72°
1.8849555921538759㎭ deg 108°
2.5132741228718345㎭ deg 144°
3.141592653589793㎭ deg 180°
3.7699111843077517㎭ deg 216°
4.39822971502571㎭ deg 252°
5.026548245743669㎭ deg 288°
5.654866776461628㎭ deg 324°
6.283185307179586㎭ deg 360°

shows the series in radians converted to degrees.

Currency Conversions

z^3 can automatically convert currencies.

b=(100$<+>3020¢);

gives the result

13020 cent.

b<>$;

gives

130.2 dollar.

With internal and external mappings to currency conversion dates, z^3 is able to do international currency conversions also.

(100..1000..100)<>USD<>INR

Numeric Units UNITSOF
100USD INR 6680.820948336871INR
200USD INR 13361.641896673742INR
300USD INR 20042.462845010614INR
400USD INR 26723.283793347484INR
500USD INR 33404.10474168436INR
600USD INR 40084.92569002123INR
700USD INR 46765.7466383581INR
800USD INR 53446.56758669497INR
900USD INR 60127.388535031845INR
1000USD INR 66808.20948336872INR


We can override internal conversion rates by using SETCONVERSION.

SETCONVERSION(1<>euro,1<>dollar,1.1)

PRINTCONVERSION();

can give the recently set conversion rates.

1<>€<>$

gives 1 euro to convert to 1$.

SETCONVERSION(1$,1€,0.9);

shows the following on PRINTCONVERSION(): {

  dollar:euro: 0.9,
  euro:dollar: 1.1111111111111112

}


MORE

((rad2piby10)<>rad<>deg)@SIN .graphin() //did not work in safari. (1..10)<>kg


1$<>1₹ // without conversion will fail.

(1..100)<>℃<>℉

SETCONVERSION(1<>€,1<>$,1.1); (1..100)<>€<>$

SETCONVERSION(1<>€,1<>$,1.10); (1..1000..10)<>€<>$

SETCONVERSION(1<>€,1<>$,1.10); (0..1000..20)<>€<>$

UNITIFY([1m,2m,3cm])

SUM(UNITIFY([1m,2m,3mm]))

(100$<+>300¢<+>30¢)<>$ PMT(4%,12,1000$,120000¢,0)

PMT(4%,12,1000$,1200.00¢,0) PMT(4%,12,1000$,120000¢,0)

1<>gal<>l 1<>l<>oz

(1..100)<>l<>ul 1Pa<>atm

E:=(m<>kg)<*>(SPEEDOFLIGHT()<^>2); b=E(2g); ConvertToUnitOfNature(b,"energy")

1m<>>1cm;

[1m,2m]<>>[1cm,200cm];

[1m,2m]<>=>[1cm,200cm];

[1m,2m]<<>[1cm,200cm];

[1m,2m]<<>[1cm,200cm];

[1m,2m]<==>[1cm,200cm];

[1m,2m]<!=>[1cm,200cm];

[1m,2m]<<=>[1cm,199.99cm];

[1m,2m]<<=>[1cm,200.01cm];

((1..10)<>m)<>>3m;

((0.1..10)<>m)<>>30cm


CONSTANT("G") CONSTANT("G")<*>1kg<*>110kg</>(6000m<^>2) // did not work.

(CONSTANT("G")<*>1kg<*>110kg)</>((6000m)<^>2) // how to bracket the units to be inside and ignore < etc? // ## can be used to name variables with spaces in them. // the actual variable is named by removing the spaces. // otherwise it goes into code as it is. ##weight of zone=3m; ++(##weight of zone);

##weight of zone=3m; a=3.4mm<+>(##weight of zone);

//%G is gravitational constant GF:=%G*m1*m2/r^2; GF(1,2,300)

v:=u+%g*t; // this uses %g as default g value v(1,2)

%planck %boltzmann; %planck length;

PRINTCONVERSIONS() CONSTANTS() CONVERT()

A¹=34; A=[23,4,5,5]; /* no array indexing on subscript yet. Will decide on that later. */ A¹=[23,4,5,5] A¹[2]

a=%gravit; b=30<*>a

a=%gravit; b=(1..10)<*>a

E:=m<>kg<*>%c<^>2; E(1000kg) E(1000kg<>lbm) // - will gave same result as 1000kg E(1000lbm) //lbm is used for units of lb mass.

// %G<*>1kg<*>110kg(6000m<^>2) // %G<*>1kg<*>110kg((6000m)<^>2) // -did not work. Said 7.34149141e-9Nm3UNITPOWERUNITSOF %G<*>1kg<*>110kg<*>((6000m)<^>2)

%G<*>1kg<*>110kg</>((6000m)<^>2)


// make this work. 1..100 @> x.txt; // send output to a <@ x.txt; // read input from a;

1.3J<>GeV 1.3J<>eV

1J<>l.atm; // 0.0098692latm 1J<>(l.atm-1) // this should fail. and will keep original units. maybe safer. 1m2<>in2 1m²<>in²

10m2<>are 1m2<>are

100m2<>acre

E:=m<>kg<*>%c<^>2; b=E(1000kg)<>J

   c=b<>eV;

[b,c]

1..100.$("[SIN(x),COS(x),TAN(x)]") 1..100.$([SIN,COS,TAN]) worked. 1..100.$("[x,x^2,x^3,x^4,x^3+x^4,SIN(x)]") works 1..100.$("[SIN(x),COS(x),TAN(x)]") 1..100.$([SIN,COS,TAN]) x=SERIESOF("1/x",9,10) //this is to from in parameter sequence. x=SERIESOF("1/x",19,10) SERIESOF("1/x",10,5) x=SERIESOF "1/LOG(x,2)" 100 1 x=SERIESOF "1/log2x" 100 91 //removed: 1..10.$_([+,-]) 1..10.$_([SUM,MINUS]) //removed: 1..10.$_|+| EXPOF(5) [SIN,COS]@[1..100] 1..10.$_("+") 1..10.$_("+") 1..10@["+"] 1..10@"+"

(1..100)<>m<+>10cm

MAGICSQUARE(3).$$(SUM) MAGICSQUARE(3).$$$(SUM) MAGICSQUARE(3).$_(SUM)

a=1m<>mm<+>400km 1m<>eor // should give nothing as there is no such conversion. (((1..100)<>m)<^>2)<>are

(1..1000)<>$ (((1..100)<>m)<^>2)<>km2 // why chinese headers here?

(1..100)m<>cm

F=%G<*>100kg<*>10g</>((100km)<^>2);

1.3J<>GeV //check this

velocity=3<>(m/sec); time=1hr; velocity<*>time;

1(g.m)<>(mg.cm)

a=LAZYRANGE(1,100) a(1..100) // generate numbers in the range at that interval, without having to generate the array ahead of time. Useful in things like INTEGRALS etc. a() a=LAZYOBJECT(1,100,1000) // can even take a(0.1); a.islazyrange()


1(kg.m2s-2)<>(N.m) 1(kg.m2s-2)<>J 1(kg.m2s-2)<>(N) // also should work as we want to get rid of the /s here in this case. 1(kg.m2s-2)<>(N.m2) // should fail. 1(kg.m2s-2)<>(J/s) // should fail. 1(kg.m2s-3)<>(J/s) 1(kg.m2.s)<>(J/s) // should this fail? it works now.

12(g.m-1/s)<>(g.cm) // should fail. 12(g.m)<>(g.mm) // should not fail. 12(g.m)<>(g.cm) // should not fail.

12(g.m)<>(g.s) // should fail. original should be returned. 12(g.m)<>(g.mm) 12(g.m)<>(g.s) 12(g.m-1)<>(g.mm-1) 12(g.m-1/s)<>(g.cm-1) // converts, but this is ok, since /s on left sometimes we want to get rid off for some reason for using it on another calculation. Say N/s but you only want to use the N on it. 1(kg.m2/s2)<>e // how to make this conversion?

1(kg.m2/s2)<>J<>e

1.3(kg.m2/s2)<>Jo // would fail and original will be kept.

(((1..100)<>m)<^>2)<>are (1..100)<>are [1cm2,2m2]<>are %pi*34; %e; %avo;

q=1(mol/s); heat=%avo<*>q;

1Pa<>atm 1atm<>psi 1atm<>hPa

a=1<>(kg/m.s-2)<>Pa<>torr 1J<>BTU 1ly<>m 10ly<>m<>km

1atm<>inHg<>mmHg

1atm<+>1bar (1atm<+>1bar)<>atm 1km<>m<>lightyear

1lightyear<>km

1lightyear<>pc

1m<>ly

1km<>ly //seemed off. this is possibly correct. (1km<+>1ly)<>km

1Å<>km

1Å<>m

(1..100)<>AU<>m

1degree<>arcminute

1Tsec<>sec

1(m/s)<>(km/hr) 1(km/s)<>(km/hr)

1(cal/mn)<>(J/sec) // d

1(kg/m3)<>(slug.ft-3)

2(rad/sec)<>rpm // did not convert. not sure why.

(1..100)<>USD<>EUR

SUPPORTEDUNITS()

1nibble<>bit 102400000000bit<>MB 1kB<>MB // seems wrong. 1kB<>Mb 1(kb)<>(bit) Pi<>(rad/sec)<>rpm 1(rad/sec)<>rpm 1(rad/mn)<>rpm (1(rad/mn)<>rpm)*2*Pi // should give 1. 1(rotation/mn)<>rpm 1(cycle/mn)<>(rad/mn)

1(cycle/mn)<>rpm

60rad<>deg 60rad<>deg<>rotation

1MB<>kB 1B<>kB 1MB<>B 1kB<>B

a=1(kg/m/s-2/t3) a=1(kg/m/s-2/t3) a=1(kg/m/s-2/t3) a=1(kg/m/s-2/t3) a=1<>(kg/m.s-2) // this worked though.

1(kg/m3)<>(slug/ft^3) // will not work due to ^. 1(kg/m3)<>(slug/ft3) //works 1(kg/m3)<>(slug.ft-3) //works

1(s-1)<>Hz 1(mn-1)<>Hz

velocity=3<>(m/s); time=1hr; velocity<*>time;

(((1..100)<>m)<^>2)<>acre

((1..100)<>m)<^>2