First project – Step 2-C: Final model
Determination of the final mathematical model for the test.
In the previous article we saw that our flask calibration test could be represented by the following diagram;
Breaking down the input magnitudes in their contributions we would get:
- Ml = Ml_cal + SMl_res + SMl_rep, where the suffixes “cal”, “res” and “rep” will be by calibration, instrument resolution and repeatability respectively. The prefixes “S” indicate that this component will have zero value since it is added only for the purpose of evaluation of uncertainties.
- Mv = Mv_cal + SMv_res
- The temperature, as we said before will be obtained from an average, so we can break down the equation in this average of readings. On the other hand, this thermometer has corrections. We could add this correction value (corr_t) to the average as a constant value without uncertainty, since this will be associated to the original values of temperature.
t = (ti + tf) / 2 + corr_t - but each one of these values will be affected by the calibration and resolution of the thermometer. So:
ti = ti_cal + Sti_res
tf = tf_cal + Stf_res
Therefore to conclude this step 2:
- We write the complete model in the text area for the Set of equations:
V20 = ((Ml-Mv) / (Dens_w-Dens_a)) * (1- (Dens_a / Dens_b)) * (1-CDT * (t-20))
Ml = Ml_cal + SMl_res + SMl_rep
Mv = Mv_cal + SMv_res
t = (ti + tf) / 2 + corr_t
ti = ti_cal + Sti_res
tf = tf_cal + Stf_res - We fill the parameters grid with the following data:
| V20 |
ml
|
Volume contained at 20 ºC |
|---|---|---|
| Ml |
ml
|
Mass of the flask full with water up to calibration mark |
| Mv |
ml
|
Mass of empty flask |
| Dens_w |
g / ml
|
Filling water density |
| Dens_a |
g / ml
|
Density of the air |
| Dens_b |
g / ml
|
Density of weighing scale adjustment masses |
| CDT |
1 / ºC
|
Coefficient of thermal deformation |
| t |
ºC
|
Average temperature along the test |
| Ml_cal |
ml
|
Flask mass including calibration uncertainty |
| SM_res |
ml
|
Contribution of uncertainty of Ml due resolution of the weighing scale |
| SM_rep |
ml
|
Contribution of uncertainty of Ml due repeatability |
| Mv_cal |
ml
|
Empty flask mass including calibration uncertainty |
| SMv_res |
ml
|
Contribution of uncertainty of Mv due resolution of the weighing scale |
| ti |
ºC
|
Initial temperature of the test |
| tf |
ºC
|
Final temperature of the test |
| corr_t |
ºC
|
Temperature correction |
| ti_cal |
ºC
|
Initial temperature with calibration uncertainty of the termometer |
| Sti_res |
ºC
|
Contribution of uncertainty of ti due thermometer resolution |
| tf_cal |
ºC
|
Final temperature with calibration uncertainty of the termometer |
| Stf_res |
ºC
|
Contribution of uncertainty of tf due thermometer resolution |
More help
- First project – Step 1
- First project – Step 2-A: Basic model
- First project – Step 2-B: Input uncertainties
- First project – Step 2-C: Final model
- First project – Step 3.
- First project – Results.