Skip to Content
Last modified by Mengting Qiu on 2024/09/02 17:23
From version 28.1
edited by Mengting Qiu
on 2024/09/02 17:23
Change comment: There is no comment for this version
To version 6.1
edited by Mengting Qiu
on 2024/09/02 13:49
Change comment: There is no comment for this version

Summary

Details

Page properties
Content
... ... @@ -16,135 +16,43 @@
16 16  In some case, the measurement and real value are in different range, but they are both linear, we have to calculate the real value with the measurement we can use a simple Linear Calibration.
17 17  
18 18  
19 -== 2.1 Solve the linear relationship manually ==
19 +**Example:** we have a water level probe, the measurement range is 0 ~~ 10 meters, and the output is 4~~20mA, this means the when the water level is 0 meter, the output is 4mA, when the water level is 10 meters, the output is 20mA.
20 20  
21 -
22 -(% style="color:blue" %)**Example:**(%%) we have a water level probe, the measurement range is 0 ~~ 10 meters, and the output is 4~~20mA, this means the when the water level is 0 meter, the output is 4mA, when the water level is 10 meters, the output is 20mA.
23 -
24 24  We can make a coordinate axis as below:
25 25  
26 -1. (% style="color:#4f81bd" %)**Y**(%%) axis is the real value, from 0~~10 meters
27 -1. (% style="color:#4f81bd" %)**X**(%%) axis is the probe output , from 4~~20mA
23 +1. (% style="color:blue" %)**Y**(%%) axis is the real value, from 0~~10 meters
24 +1. (% style="color:blue" %)**X**(%%) axis is the probe output , from 4~~20mA
28 28  
29 29  We use two points to make the linear line: Point1(x1,y1) = (4,0), Point2(x2,y2)= (20,10).
30 30  
31 -Since the reading is linear, all (% style="color:#4f81bd" %)**probe output**(%%) and (% style="color:#4f81bd" %)**real value**(%%) is on this line, so we can calculate the real value by probe output in two steps:
28 +Since the reading is linear, all (% style="color:blue" %)**probe output**(%%) and (% style="color:blue" %)**real value**(%%) is on this line, so we can calculate the real value by probe output in two steps:
32 32  
33 -* **Step1:** Get (% style="color:#4f81bd" %)**realk(Slope)**(%%) for the line:
30 +* **Step1:** Get (% style="color:blue" %)**k(Slope)**(%%) for the line:
34 34  
35 35   k=(y2-y1)/(x2-x1) = (10-0)/(20-4) =10/16= 0.625
36 36  
37 -* **Step2:** Get (% style="color:#4f81bd" %)**real value( y )**(%%):
34 +* **Step2:** Get (% style="color:blue" %)**kreal value(y)**(%%):
38 38  
39 - k =(y-y1)/(x-x1)  
36 +k=(y-y1)/(x-x1)  
40 40  
41 - ~-~-> y = k*(x-x1)+y1 = 0.625 * (x-4) + 0.
38 +~-~-> y = k*(x-x1)+y1 = 0.625 * (x-4) + 0.
42 42  
43 - ~= 0.625 * (x-4)
40 + ~= 0.625 * (x-4)
44 44  
45 -Thus, we can introduce x-values to the already obtained equations to derive the corresponding y-values:
42 +When x=12mA , y=5 meters
46 46  
47 -When x=12 mA , y=5 meters
44 +When x=8mA, y= 2.5 meters
48 48  
49 -When x=8 mA, y=2.5 meters
50 50  
47 +A more general formular:
51 51  
52 -**A more general formular:**
49 +Y=(y2-y1)/(x2-x1)* (x-x1) + y1
53 53  
54 -(% style="color:blue" %)**Y=(y2-y1)/(x2-x1)* (x-x1) + y1**
55 55  
52 +[[image:image-20240902114541-1.png||height="492" width="874"]]
56 56  
57 -Calibration Curve Schematic:
58 58  
59 -[[image:image-20240902114541-1.png||height="336" width="596"]]
60 60  
61 -
62 -== 2.2 Performing linear calibration curves in Excel ==
63 -
64 -
65 -In addition, we can also perform calibration curves in Excel and directly obtain linear equations by statistics of X and Y values.
66 -
67 -Citing the same example above, (% style="color:#4f81bd" %)**X**(%%) and (% style="color:#4f81bd" %)**Y**(%%).
68 -
69 -
70 -=== Step 1: Create chart ===
71 -
72 -
73 -A simple spreadsheet with two columns: X values and Y values.
74 -
75 -[[image:image-20240902160516-1.png||height="404" width="561"]]
76 -
77 -* Start by selecting the data you want to plot in the chart.
78 -* First, select the X-Value column cell, then press the Ctrl key, and finally click the Y-value column cell.
79 -
80 -[[image:image-20240902160755-2.png||height="394" width="562"]]
81 -
82 -* Go to the "(% style="color:#4f81bd" %)**Insert**(%%)" TAB, navigate to the "(% style="color:#4f81bd" %)**Chart**(%%)" menu, and then select the first option in the "(% style="color:#4f81bd" %)**Scatter**(%%)" drop-down list.
83 -* A chart will appear with the data points in the two columns.
84 -
85 -[[image:image-20240902161202-3.png||height="453" width="824"]]
86 -
87 -* Right-click on one of the blue dots and select the (% style="color:#4f81bd" %)**"Add Trendline" **(%%)option.
88 -
89 -[[image:image-20240902161711-4.png||height="490" width="681"]]
90 -
91 -* A straight line will appear on the chart.
92 -
93 -On the right side of the screen, the Format Trendline menu will appear. Check the boxes next to (% style="color:#4f81bd" %)**"Show formulas on chart" **(%%)and (% style="color:#4f81bd" %)**"Show R-squared values on chart"**(%%).
94 -
95 -The R-squared value is a statistic that tells you how well the line fits the data. The best R-squared value is **1.000**, which means that every data point touches the line.
96 -
97 -Because the ideal data example is used, the R-squared value in this case is 1.
98 -
99 -As the difference between the data points and the line increases, the R-squared value decreases, with **0.000** being the lowest possible value.
100 -
101 -The equation is of the form (% style="color:blue" %)**"y = kx + b"**(%%),(% style="color:blue" %)** **(%%)where (% style="color:blue" %)**k**(%%) is the slope and (% style="color:blue" %)**b**(%%) is the y-intercept of the line.
102 -
103 -[[image:image-20240902161857-5.png||height="559" width="1103"]]
104 -
105 -* Calibration is complete. The user can customize the chart by editing the title and adding the axis title.
106 -
107 -[[image:image-20240902163527-7.png||height="349" width="656"]]
108 -
109 -
110 -=== Step 2: Calculate the line equation and R-squared statistic ===
111 -
112 -* Write the (% style="color:#4f81bd" %)**Slope formula**(%%) in the formula bar according to the original x and y values statistics table.
113 -
114 -[[image:image-20240902164104-8.png||height="503" width="492"]]
115 -
116 -* Write (% style="color:#4f81bd" %)**Intercept formula**(%%) in the formula bar according to the original x and y value statistics table.
117 -
118 -[[image:image-20240902164156-9.png||height="525" width="488"]]
119 -
120 -* Write (% style="color:#4f81bd" %)**CORREL's squared formula**(%%) in the formula bar based on the original x and y statistics table.
121 -
122 -The CORREL function returns "R", so we have to square it to compute "R squared".
123 -
124 -[[image:image-20240902164503-11.png||height="523" width="743"]]
125 -
126 -* These values match those shown in the chart.
127 -
128 -[[image:image-20240902164910-12.png||height="420" width="897"]]
129 -
130 -
131 -=== Step 3: Set up formulas to quickly calculate X and Y values. ===
132 -
133 -
134 -* The equation of the best fitting line is "Y-value = SLOPE * x-value + INTERCEPT", so the solution of "y-value" is obtained by multiplying X value and SLOPE, and then INTERCEPT is added.
135 -
136 -A simple formula table for calculating Y value automatically with input X value is obtained.
137 -
138 -[[image:image-20240902171627-15.png||height="440" width="754"]]
139 -
140 -
141 -* The X value based on the Y value is solved by subtracting INTERCEPT from the Y value and dividing the result by SLOPE: "x-value = (y-value-intercept)/SLOPE".
142 -
143 -A simple formula table for automatically calculating X value based on the input Y value is obtained.
144 -
145 -[[image:image-20240902171909-16.png||height="604" width="756"]]
146 -
147 -
148 148  = 3. Case examples =
149 149  
150 150  
... ... @@ -151,29 +151,31 @@
151 151  Some case for example which we can use Linear Calibration:
152 152  
153 153  
154 -(% style="color:blue" %)**Case 1: Calibrate Microwave Radar Readling.**
62 +Case 1: Calibrate Microwave Radar Readling.
155 155  
156 156  The microwave radar reading might effect by the OUM(Object Under Measured), but the reading still linear. In this case, we can measure the closest(x1,y1) and the farthest point(x2,y2). Where the x is reading in platform, y is the real value. And use above method to calibrate.
157 157  
158 158  
159 -(% style="color:blue" %)**Case 2: Calibrate the Soil EC base on SE01 soil sensor raw EC reading.**
67 +Case 2: Calibrate the Soil EC base on SE01 soil sensor raw EC reading.
160 160  
161 161  The SE01 probe is calibrated via mineral soil. The reading for other soil will be different by still in linear, In this case, we can measure two points (x1,y1) and (x2,y2). Where the x is reading of Raw EC, y is the real EC for the soil. And use above method to calibrate
162 162  
163 163  
164 -(% style="color:blue" %)**Case 3: use water level probe to calibrate for oil.**
72 +Case 3: use water level probe to calibrate for oil.
165 165  
166 166  Oil has different density vs water, but we can still use the immersion type water level pressure sensor to get the oil level. In this case, we can measure two points (x1,y1) and (x2,y2). Where the x is reading of water level, y is the oil level. And use above method to calibrate
167 167  
168 168  
169 -(% style="color:red" %)**Notice for Linear Calibrate:**
77 +Notice for Linear Calibrate:
170 170  
171 -(% style="color:red" %)**1. k(Slope) is very important, We can measure more points to calculate the most accuracy k. **
79 +1. k(Slope) is very important, We can measure more points to calculate the most accuracy k.
80 +1. Make sure the mapping is linear, and choose two calibrate points as “far” as possible.
172 172  
173 -(% style="color:red" %)**2. Make sure the mapping is linear, and choose two calibrate points as "far" as possible.**
174 174  
175 175  
176 176  
177 177  
178 178  
87 +
88 +
179 179  
image-20240902160516-1.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -31.2 KB
Content
image-20240902160755-2.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -29.0 KB
Content
image-20240902161202-3.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -74.0 KB
Content
image-20240902161711-4.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -66.9 KB
Content
image-20240902161857-5.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -48.1 KB
Content
image-20240902163114-6.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -59.7 KB
Content
image-20240902163527-7.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -25.8 KB
Content
image-20240902164104-8.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -27.2 KB
Content
image-20240902164156-9.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -24.4 KB
Content
image-20240902164500-10.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -34.4 KB
Content
image-20240902164503-11.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -34.4 KB
Content
image-20240902164910-12.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -33.2 KB
Content
image-20240902171200-13.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -64.5 KB
Content
image-20240902171417-14.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -36.4 KB
Content
image-20240902171627-15.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -37.9 KB
Content
image-20240902171909-16.png
Author
... ... @@ -1,1 +1,0 @@
1 -XWiki.ting
Size
... ... @@ -1,1 +1,0 @@
1 -54.6 KB
Content