HP 48G: Scientific Applications
Calculators Featured: HP 48G, HP 48G+, HP 48GX
Theoretic Freezing Level
The program FRZLVL calculates the theoretical freezing level in feet above sea level given the outside temperature at a given altitude. The results are displayed in feet (the feet unit is attached).
HP 48G Program: FRZLVL
<< "FREEZING LEVEL"
{ { "ALT:" "DEFAULT FT" }
{ "TEMP:" "DEFAULT °C" } }
{ } { } { }
IF INFORM
THEN OBJ→ DROP DUP TYPE
IF 13 == THEN '1_°C' CONVERT
ELSE '1_°C' →UNIT
END SWAP DUP TYPE
IF 13 == THEN '1_ft' CONVERT
ELSE '1_ft' →UNIT
END SWAP '1000_ft/°C'
* DUP2 2 / +
"DRY" →TAG 3 ROLLD
1.5 / + "WET" →TAG END >>
Instructions
1. Run FRZLVL
2. ALT: Enter altitude. You can attach units if you want, the default is altitude is in feet.
3. TEMP: Enter outside air temperature. You can attach units if you want, the default unit is degrees Celsius (°C).
4. Results: freezing dry level in feet and freezing wet level in feet.
Example
Altitude: 1,750 ft
Temperature: -2°C (28.4°F)
Results:
DRY: 750_ft
WET: 416.666666667_ft
Source:
Hewlett Packard "Predicting Freezing Levels" HP 65 Aviation Pac 1. Hewlett Packard. 1974
Lens Calculations
Variables
Please note the inequality restrictions.
R = radius of curvature
D = diameter of the lens, D ≤ 2*R
S = sag S ≤ R
θ = tangent angle between lens axis and reflection
HP 48G Program: LENSANG
<< 'R=(D^2+4*S^2)/(8*S)' STEQ
{ { "R/D" << 'D' STO 'R' STO EQ 'S' 0 ROOT 'S' →TAG >> }
{ "R/S" << 'S' STO 'R' STO EQ 'D' 0 ROOT 'D' →TAG >> }
{ "D/S" << 'S' STO 'D' STO EQ 'R' 0 ROOT 'R' →TAG >> }
{ "→θ" << 'D' RCL 'R' RCL 'S' RCL - 2 * / ATAN 'θ' DUP2 STO →TAG >> } }
TMENU >>
Instructions
1. Run LENSANG. A temporary custom menu appears.
2. Enter two known amounts and press the appropriate key to store the variables:
If R and D are known: R [ ENTER ] D [ F1 ]
If R and S are known: R [ ENTER ] S [ F2 ]
If D and S are known: D [ ENTER ] S [ F3 ]
The third variable between R, D, and S is calculated and displayed as a result.
3. Press [ F4 ] to calculate the angle, θ.
Results are stored in the variables R, S, D, and θ.
Examples
Known: R = 5.8, D = 7.6
LENSANG 5.8 [ ENTER ] 7.6 [ F1 ] (R/D)
Result: S: 1.41821953996
[ F4 ] (θ). Result: θ: 40.9327245742
Known: D = 11, S = 9
LENSANG 11 [ ENTER ] 9 [ F3 ] (D/S)
Result: R: 6.18055555556
[ F4 ] (θ). Result: θ: -62.8591312297
Source:
Tuchscherer, L.D. "Lens Calculations - SAG, ANGLE, MIN/MAX" HP 67 Optics Hewlett Packard. 1978.
Period of a Pendulum
The program PENDULUM calculates the period of a pendulum given two parameters:
ANGLE: the angle that the pendulum swings out. The angle must be entered in radians.
LENGTH: The length of the pendulum in meters.
Unlike most calculations, the program uses an Legendre elliptic integral of the first kind to increase accuracy.
T = 4 * √(L / g) * ∫( dx / √(1 - k^2 * sin^ x), x, 0, π/2) where k = sin(α/2)
g = Earth's gravitational constant = 9.80665 m/s^2
This program does not use units.
HP 48G Program: PENDULUM
<< RAD
"PENDULUM"
{ { "ANGLE:" "IN RADIANS" }
{ "LENGTH:" "IN METRES" } }
{ } { } { }
IF INFORM
THEN OBJ→ DROP
9.80665 / √ 4 *
SWAP 2 / SIN SQ 0 θ π 2 /
→NUM 3 ROLL 'X'
SIN SQ * 1 SWAP - √
INV 'X' ∫ →NUM *
"PERIOD" →TAG END >>
Example
ANGLE: π/6 (enter this as 'π/6')
LENGTH: 1.5 (m)
Result:
PERIOD: 2.50011881685 (s)
Source:
Steers, Hugh. "The Pit & Pendulum" Datafile. ISSN 1352-8254. Handheld and Portable Computer Club. V29 N1. January - March 2010
Eddie
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