Eval » Historie » Version 22
Maximilian Seesslen, 20.07.2023 17:53
| 1 | 1 | Maximilian Seesslen | h1. Eval |
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| 2 | |||
| 3 | h1. Overall design |
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| 4 | |||
| 5 | * 4 x red+green LEDs for condition |
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| 6 | * Restart button |
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| 7 | 10 | Maximilian Seesslen | * Iterate over the ADC channels and get Voltage level |
| 8 | 13 | Maximilian Seesslen | * Self-Calibrating via MOSFET (shortcuit cable interface) |
| 9 | 18 | Maximilian Seesslen | * draw 100mA. Why? Sonst habe ich keinen Spannungsteiler. Je mehr Strom desto hoeher der Spannungsabfall; optional via mosfet.; 3/0,1= 30 Ohm |
| 10 | 17 | Maximilian Seesslen | * ADC loesst theoretisch auf "3 / 4096 = approx. 0,0007" Volt auf. |
| 11 | 4 | Maximilian Seesslen | * Die Kabel haben AWG28, 212.9 Ohm/km, 1.4 A nach erde, 0.23 A versorgung |
| 12 | 7 | Maximilian Seesslen | * 0,2129 Ohm/m; 1,0645 Ohm/5m; 2,129 Ohm/10m; |
| 13 | 4 | Maximilian Seesslen | * https://de.wikipedia.org/wiki/E-Reihe#/media/Datei:E12_values_graph.svg |
| 14 | 20 | Maximilian Seesslen | * Buzzer would be nice for indication; durchklingeln. Da werde ich lieber Multimeter nehmen. Ist aber kein Aufwand. |
| 15 | * PWM Output |
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| 16 | 1 | Maximilian Seesslen | * Pinsocket connected to wires to measure resistance/Voltage directly |
| 17 | * https://www.aeq-web.com/spannungsteiler-microcontroller-berechnen-und-dimensionieren/ |
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| 18 | * Spannungen einzeln schaltbar damit auch kurzschluesse detektiert werden koennen |
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| 19 | 20 | Maximilian Seesslen | |
| 20 | 19 | Maximilian Seesslen | h1. Schema |
| 21 | 1 | Maximilian Seesslen | |
| 22 | 22 | Maximilian Seesslen | <pre> |
| 23 | 3V |
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| 24 | | |
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| 25 | | | Cable |
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| 26 | |-------------->ADC |
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| 27 | | | 30Ohm |
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| 28 | | |
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| 29 | === |
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| 30 | 17 | Maximilian Seesslen | |
| 31 | 22 | Maximilian Seesslen | </pre> |
| 32 | 17 | Maximilian Seesslen | |
| 33 | 1 | Maximilian Seesslen | h1. Theoretische Spannungen bei AWG28 |
| 34 | 13 | Maximilian Seesslen | |
| 35 | 17 | Maximilian Seesslen | theoretically an device that draws 0,1A, 5V and 5m AWG28 cable: |
| 36 | 13 | Maximilian Seesslen | U2=((5*50)/ (50+1,0645) ) = 4,8957691; that should work |
| 37 | 1 | Maximilian Seesslen | |
| 38 | 17 | Maximilian Seesslen | theoretically an device that draws 0,5A, 5V and 10m AWG28 cable: |
| 39 | 1 | Maximilian Seesslen | U2 = ( (5*10) / (10+2,129) ) = 4,1223514 V |
| 40 | 17 | Maximilian Seesslen | |
| 41 | theoretically an device that draws 0,1A, 3V and 5m AWG28 cable: |
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| 42 | U2=((3*30)/ (30+1,0645) ) = 2,8971978; that should work |
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| 43 | |||
| 44 | theoretically an device that draws 0,1A, 3V and 10m AWG28 cable: |
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| 45 | U2=((3*30)/ (30+2,129) ) = 2,8012076 |
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| 46 | |||
| 47 | theoretically an device that draws 0,25A, 3V and 10m AWG28 cable: |
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| 48 | U2= (3 * 12) / (12 + 2,129) = approx. 2,547951 |
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| 49 | |||
| 50 | theoretically an device that draws 0,5A, 3V and 10m AWG28 cable: |
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| 51 | U2= (3 * 6) / (6 + 2,129) = approx. 2,2142945 |
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| 52 | U2= (3 * 6,8) / (6,8 + 2,129) = approx. 2,2846903 |
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| 53 | 13 | Maximilian Seesslen | |
| 54 | 12 | Maximilian Seesslen | h1. Calculations I |
| 55 | |||
| 56 | 4 | Maximilian Seesslen | U2=((U*R2)/R_GES) |
| 57 | |||
| 58 | 5 | Maximilian Seesslen | U |
| 59 | 4 | Maximilian Seesslen | R*I |
| 60 | |||
| 61 | 5V/0,1A= 50 Ohm |
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| 62 | 5V*0,1A= 0,5 W |
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| 63 | |||
| 64 | 7 | Maximilian Seesslen | 5V/0,5A= 10 Ohm |
| 65 | |||
| 66 | 5 | Maximilian Seesslen | RGes = R1+R2 = 50 |
| 67 | |||
| 68 | 7 | Maximilian Seesslen | 3V=(5*R2)/50 |
| 69 | *R2 = (3*50)/5 = 30 -> 27 |
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| 70 | R1 = 22* |
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| 71 | RGES = 49 |
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| 72 | 1 | Maximilian Seesslen | |
| 73 | U2 = 5*27/49 = 2,755102 |
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| 74 | |||
| 75 | h1. Calculations II |
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| 76 | 12 | Maximilian Seesslen | |
| 77 | 1 | Maximilian Seesslen | * Ein Kabel >= 10m soll durchfallen. Koennen trotzdem groessere Wiederstaende verwendet werden? |
| 78 | |||
| 79 | 13 | Maximilian Seesslen | Ohne Widerstand: |
| 80 | 1 | Maximilian Seesslen | |
| 81 | 13 | Maximilian Seesslen | U2 = 2,755102 |
| 82 | 1 | Maximilian Seesslen | |
| 83 | 13 | Maximilian Seesslen | Obige werte 1fach, 10m Kabel: |
| 84 | |||
| 85 | R2 = 27 |
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| 86 | R1 = 22 |
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| 87 | mit 10m |
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| 88 | U2 = (5*27)/(49+2,129) = 2,6403802 |
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| 89 | 2,755102-2,6403802=0,1147218 |
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| 90 | 0,1147218/0,00073242188 = 156,6335 |
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| 91 | |||
| 92 | Obige werte 10fach, 10m Kabel: |
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| 93 | |||
| 94 | R2 = 270 |
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| 95 | R1 = 220 |
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| 96 | mit 10m |
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| 97 | U2 = (5*270)/(490+2,129) = 2,7431832 |
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| 98 | |||
| 99 | Bei 12Bit ADC: 3 / 4096 = approx. 0,00073242188 V pro ADC-Wert. |
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| 100 | 2,755102-2,7431832=0,0119188 |
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| 101 | 0,0119188 / 0,00073242188 = approx. 16,273135. Thats not super much |
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| 102 | |||
| 103 | 16 | Maximilian Seesslen | h1. Calculations III |
| 104 | |||
| 105 | 10 | Maximilian Seesslen | h1. Keyfeatures |
| 106 | |||
| 107 | * Cable checker |
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| 108 | * Buzzer Durchgangspruefer |
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| 109 | * PWM Output |
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| 110 | 7 | Maximilian Seesslen | |
| 111 | 1 | Maximilian Seesslen | h1. MCU |
| 112 | 2 | Maximilian Seesslen | |
| 113 | 1 | Maximilian Seesslen | * "stm32f051c4":https://www.mouser.de/datasheet/2/389/stm32f051c4-1851079.pdf |
| 114 | ** I have 17; |
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| 115 | 2 | Maximilian Seesslen | ** 16 ADC channels |
| 116 | * STM32G030C8T6 |
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| 117 | 3 | Maximilian Seesslen | ** nearly same specs but smaller footprint; LQFP 48 |
| 118 | 1 | Maximilian Seesslen | ** 2,68€ inc. Mwst. |
| 119 | 13 | Maximilian Seesslen | ** ADC faster |
| 120 | ** Mentions an 16Bit ADC value via oversampling, but thats complicated: adding white noise in order to calculate further 2 bits by software. Every MCU can do that. |
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| 121 | 21 | Maximilian Seesslen | |
| 122 | * 4 ADC IN |
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| 123 | * 4 Spannungs schalten |
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| 124 | * 4 Kalibrierung schalten |
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| 125 | * 2 LED Heartbeat/User |
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| 126 | * 4 LED kabel ROT |
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| 127 | * 4 LED kabel Gruen |
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| 128 | * 4 LED kabel Orange |
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| 129 | * 1 Input button |
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| 130 | * 2 Output PWM |