MathNotepad_CASUAL
copia-incollare su MathNotePad:
(attenzione: per usare più volte la stessa funzione mettere e togliere il ";" finale SPORCO TRUCCO)
rndNUM()= (1+randomInt(99));
rndnum()= (1+randomInt(8));
rndUM(vett)= vett[floor((size(vett)[1]*random()))+1];
rndVAR(vett)= rndNUM() rndUM(vett);
rndvar(vett)= rndnum() rndUM(vett);
rndNUM20()= (1+randomInt(20));
w1(x)=string(format(x,1));
w2(x)=string(format(x,2));
w3(x)=string(format(x,3));
w(x)=format(x,4);
PRE=["y","z","a","f","p","n","u","m","c","d","h","k","M","G","T","P","E","Z","Y"];
rndACC()=rndVAR([ m/s^2]); # acceleration
rndBBB()=rndVAR([pT, nT, uT,mT,T]); # magnetic field
rndBFLU()=rndVAR([Wb]); # flux of magnetic field (T m2), (V s ), ( A H )
rndCAP()=rndVAR([pF, nF, uF,F]); # capacity
rndCOND()=rndVAR([S]); # conduttance (Siemen)
rndCRG()=rndVAR([pC, nC, uC,mC, C]); # charge
rndCUR()=rndVAR([pA, nA, uA,mA, A, kA]); # current
rndDEN()=rndMASS()/rndVOL(); # density
rndENRG_J()=rndVAR([peV, neV, ueV,meV, eV, keV, MeV, GeV, TeV]);
rndENRG_J()=rndVAR([pJ, nJ, uJ,mJ, J, kJ, MJ, GJ, TJ]); # Energy (Joule)
rndFORCE()=rndVAR([N]);
rndFREQ()=rndVAR([mHz,Hz,kHz,MHz,GHz,THz]); # frequency
rndIND()=rndVAR([pH, nH, uH,mH,H]); # induttance (Henry)
rndLEN()=rndVAR([pm, nm, um, mm, cm, dm, m, hm,km]); # leght
rndMASS()=rndVAR([ug,mg,g,kg,ton]); # leght
rndMOL()=rndVAR([pmol, nmol, umol, mmol, mol]); # mole
rndPOT()=rndVAR([pV, nV, uV,mV, V, kV, MV, GV]); # electrical potential
rndPOW()=rndVAR([pW, nW, uW,mW, W, kW, MW, GW, TW]); # power
rndPRSS()=rndVAR([mPa,Pa,kPa,atm]); # pressure
rndRES()=rndVAR([uohm,mohm, kohm, Mohm, Gohm]); # resistance
rndSUP()=rndVAR([pm2, nm2, um2, mm2, cm2, dm2, m2, km2 ]); # surface
rndTIME()=rndVAR([s]);
rndVEL()= rndVAR([ m/s, km/h ]); # Velocity
rndVOL()=rndVAR([pm3, nm3, um3, mm3, cm3, dm3, m3, km3, ml, cl, dl, l ]) ;
a_2position()=[rndVAR([m]),rndVAR([m])];
a_2velocity()=[rndVAR([m/s]),rndVAR([m/s])];
an_2acceleration()=[rndVAR([m/s^2]),rndVAR([m/s^2])];
a_2force()=[rndVAR([N]),rndVAR([N])];
a_3position()=[rndVAR([m]),rndVAR([m]),rndVAR([m])];
a_3velocity()=[rndVAR([m/s]),rndVAR([m/s]),rndVAR([m/s])];
an_3acceleration()=[rndVAR([m/s^2]),rndVAR([m/s^2]),rndVAR([m/s^2])];
a_3force()=[rndVAR([N]),rndVAR([N]),rndVAR([N])];
# a b c d e f g h i j k l m n o p q r s t u v w x y z
# α β ψ δ ε φ γη ι ξ κ λ μ ν ο π ? ρ σ τ θ ω ς χ υ ζ
# A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
# Α Β Ψ Δ Ε Φ Γ Η Ι Η Κ Λ Μ Ν Ο Π ; Ρ Σ Τ Θ Ω Σ Χ Υ Ζ
c = speedOfLight; G = gravitationConstant; K_0= coulomb;
e = elementaryCharge; m_e=electronMass ; m_p = protonMass;
a0=bohrRadius; Na=avogadro; R=gasConstant ;
Kb=boltzmann; g=gravity ;eps_0=electricConstant;