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  1. \documentclass[11pt]{article}
  2. %Gummi|065|=)
  3. \usepackage{graphicx}
  4. \usepackage{caption}
  5. \usepackage{xcolor}
  6. \usepackage[vcentering,dvips]{geometry}
  7. \geometry{papersize={6in,9in},total={4.5in,6.8in}}
  8. %\title{\textbf{Door Alarm}}
  9. \author{Steak Electronics}
  10. \date{}
  11. \begin{document}
  12. %\maketitle
  13. \tableofcontents
  14. \textcolor{green!60!blue!70}{
  15. \section{Attiny Solar Energy Harvest Tests}}
  16. I have the following:
  17. \begin{itemize}
  18. \item Solar panels
  19. \item Attiny 10
  20. \end{itemize}
  21. To this list, I will add a supercap, and an energy harvesting IC. The goal being to load the super cap during the day, and to run 24/7. I will need an exceptionally low power micro. The super cap will need to be about 3.3V or 5V.
  22. \textcolor{green!60!blue!70}{
  23. \subsection{Micro Considerations}}
  24. The Arduino Atmega328P is not an option. I'm looking to have a current draw of only 1mA max, (ideally 500uA) when active. Moteino is also not an option for this. Those are made for batteries. I want to be battery free. A super cap, however can be used to store energy. I'll get to that shortly.
  25. For micros, I have some Attiny10 on hand, and these have a reasonably low power pull in active mode. Let's build those up first. What will the micro do? No idea. I haven't a clue.
  26. \textcolor{green!60!blue!70}{
  27. \subsubsection{Micro Notes}}
  28. Must run at 1.8V / 1MHz per front page of data sheet, for 200uA draw in active mode.
  29. \\
  30. \\
  31. \textcolor{green!60!blue!70}{
  32. \subsubsection{Energy Storage}}
  33. I don't want a battery. Let's go with a super cap. The solar panels will only be active some of the time, so I will want to harvest energy with some kind of IC into the cap when the sun is out.\footnote{Reference: www.analog.com/media/en/technical-documentation/technical-articles/solarenergyharvesting.pdf is a start. I'll need to do more research.}
  34. \textcolor{green!60!blue!70}{ \subsubsection{Make parts, not scrap}} I will
  35. want to make sure that all parts I build are perf board parts, not
  36. breadboard scrap (to be torn down and rebuilt again). This is an Attiny,
  37. so no need to test much, yet.
  38. \textcolor{green!60!blue!70}{
  39. \subsection{Programming}}
  40. To program the Attiny10, I'll use the Arduino adapter from the Junk + Arduino blog. I built it up\footnote{Had slight error where the Arduino + board wouldn't read - pins too short on headers, then the arduino wouldn't boot - due to bad connection on perf board shield. Thankfully, the USB port didn't try to run. Protection circuitry cut in on the laptop.}, and was able to Read the memory. In order to upload to the board, you will need a compiler setup. You can possibly do it in AVRGCC, but instead I opted for either Arduino IDE (via Attiny10Core which didn't work), and then went to Mplab. In order for mplab 5.25 to work, it will need XC8 compiler, and there is a pack that can be downloaded through the IDE to get Attiny10 support.
  41. It appears the AVR Dragon (which I have) can not be used. However, other programmers can be used. Pickit 4, Mkavrii, stk600, I think.
  42. \textcolor{green!60!blue!70}{ \subsubsection{Testing Arduino Loader}}
  43. Tested this with the blink\_LED.c in code folder. The code is as simple as possible.
  44. It is the following:
  45. \begin{verbatim}
  46. //#include <xc.h>
  47. #include <avr/io.h>
  48. #include <util/delay.h>
  49. int main(void)
  50. {
  51. // PB2 output
  52. DDRB = 1<<2;
  53. while(1)
  54. {
  55. // Toggle PB2
  56. PINB = 1<<2;
  57. _delay_ms(500);
  58. }
  59. }
  60. \end{verbatim}
  61. When programmed in Mplab, with XC8 compiler, and Attiny10 support, I get the following
  62. hex output:
  63. \begin{verbatim}
  64. :100000000AC020C01FC01EC01DC01CC01BC01AC01B
  65. :1000100019C018C017C011271FBFCFE5D0E0DEBF41
  66. :0A002000CDBF03D000C0F894FFCF5D
  67. :10002A0044E041B940B95FE966E871E05150604087
  68. :0A003A007040E1F700C00000F5CFB0
  69. :02004400DDCF0E
  70. :00000001FF
  71. \end{verbatim}
  72. The content of this hex isn't the focus of this passage. Instead, I want you to review the
  73. results of a D for Dump Memory, by the Arduino Loader.
  74. \begin{verbatim}
  75. Current memory state:
  76. registers, SRAM
  77. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  78. 0000: 05 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
  79. 0010: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
  80. 0020: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
  81. 0030: 00 00 00 00 00 00 03 00 00 79 00 03 00 00 00 00
  82. 0040: B7 AD AE FA 58 70 63 6B FB 5A B4 1B FF FF 35 3F
  83. 0050: 67 D7 33 43 DF 5F FB 72 C9 7D FE E9 9D C5 00 12
  84. NVM lock
  85. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  86. 3F00: FF FF
  87. configuration
  88. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  89. 3F40: FF FF
  90. calibration
  91. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  92. 3F80: 79 FF
  93. device ID
  94. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  95. 3FC0: 1E 90 03 FF
  96. program
  97. +0 +1 +2 +3 +4 +5 +6 +7 +8 +9 +A +B +C +D +E +F
  98. 4000: 0A C0 20 C0 1F C0 1E C0 1D C0 1C C0 1B C0 1A C0
  99. 4010: 19 C0 18 C0 17 C0 11 27 1F BF CF E5 D0 E0 DE BF
  100. 4020: CD BF 03 D0 00 C0 F8 94 FF CF 44 E0 41 B9 40 B9
  101. 4030: 5F E9 66 E8 71 E0 51 50 60 40 70 40 E1 F7 00 C0
  102. 4040: 00 00 F5 CF DD CF FF FF FF FF FF FF FF FF FF FF
  103. 4050: FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF
  104. 4060: FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF
  105. (...some memory omitted here for brevity...)
  106. 43E0: FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF
  107. 43F0: FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF
  108. \end{verbatim}
  109. Notice that the "AC020C01F" is set. That is from the hex. But the 01000...
  110. before it seems to be missing. Some deciphering of how the Arduino programs
  111. the Attiny is in order here. It also doesn't end the same.
  112. Regardless, when programming, the Arduino reports 70 bytes written, and
  113. likewise in the Mplab project memorymap.xml file, it also notes 70 bytes
  114. for the sketch. This lines up.\footnote{Although for an unknown reason, every command registers twice on the Arduino serial monitor, but this appears to be harmless.}
  115. The blinking LED works. Let's move on.
  116. \textcolor{green!60!blue!70}{\subsubsection{Conclusion on Arduino Programming Attiny10}}
  117. It's possible, but you have to make a dedicated jig (almost), so it might be easier to use the official programming tools. However, based on this https://www.avrfreaks.net/forum/pickit-4-and-avr-mcu I might not have a choice. So I will use the Arduino for now. But will have to devise what on board parts are req'd for programming, and incorporate into proto board layout.
  118. \textcolor{green!60!blue!70}{ \subsubsection{IO Port Switching Speed}}
  119. Using the above code without any delay\_ms, I get the following results from a default clock
  120. speed, and a 128KHz clock speed. This test was done to confirm that I could change the clock with
  121. \begin{verbatim}
  122. //Write CCP
  123. CCP = 0xD8;
  124. //change CLK to 128KHz
  125. CLKMSR = 0b01;
  126. \end{verbatim}
  127. There was no issue.
  128. \begin{verbatim}
  129. Default CLK (8MHz? or 1MHz?): 160KHz IO Switch
  130. 128KHz CLK: 2.5KHz IO Switch
  131. \end{verbatim}
  132. I am going to pursue 128KHz for starters, for lower current dissipation. Note that with the Arduino loader, it is cumbersome to test and change code as you move along. It is
  133. therefore going to be necessary to use a programmer, with a dedicated header on board.
  134. \textcolor{green!60!blue!70}{ \subsubsection{VCC 1.8V}}
  135. The lowest power supported: 1.8V can be applied, without any configuration
  136. needed. It does not affect IO switching speed (although obviously amplitude is affected).
  137. \begin{verbatim}
  138. 128KHz CLK (5.0V): 2.5256 KHz IO switch
  139. 128KHz CLK (3.3V): 2.5477 KHz IO switch
  140. 128KHz CLK (1.8V): 2.5849 KHz IO switch
  141. \end{verbatim}
  142. As voltage drops, IO increases.
  143. \\
  144. \\
  145. \textbf{VCC Dropout voltage:}
  146. \\
  147. From 1.5, it drops out at 1.248V or so. Comes back at about 1.34V
  148. \\
  149. \\
  150. Test size of 1.
  151. \\
  152. \\
  153. Can't run this with one (AA) battery, but you could with 2.
  154. \\
  155. \\
  156. Current Draw: 128KHz - IO test, 1.8V, 0.08mA (~78uA) (tested w/3478A)
  157. \\
  158. \\
  159. \textcolor{green!60!blue!70}{\subsection{Application}}
  160. First, I need a board for these and a programmer, to quickly program. Second, I need an application. I want extremely low power. Hopefully, solar with no batteries, to start. This is extremely low - that is the point. Let's keep this ridiculous.
  161. Given the power requirements put me under 1mA (with my current panels), I'm considering the following: EEPROMs would require SPI protocol. Doable, but overcomplicated for now.
  162. \\
  163. \\
  164. Eink (need to find a small and cheap enough option. So far, they have either too many pins, and/or use too much current. Something like what stores use to display prices would work, but that doesn't get the data out, only makes it readable.),
  165. \\
  166. \\
  167. Third option would be RF. That is a viable path, but not today. Let's skip that for now.
  168. \\
  169. \\
  170. Fourth option that comes to mind is IR. IR diodes, as in TV remotes, would work well here. I am choosing this as the first project. I will have dumb clients, that consist of - Attiny / IR / Sensor powered by solar. I will have a BBB that receives the IR data, and does all intelligent data gathering. To keep things simple, the IR will be binary ADC data, or otherwise sensor numbers. No SPI, no protocol complexity. That would require space on the Attiny.
  171. \\
  172. \\
  173. Let's build some boards based on the above.
  174. \\
  175. \\
  176. For sensors:
  177. While building, I came across an option. Hall effect sensors. I think also capacitive sensors can be used. This may find a use in a gate sensor, for when a driveway gate is opened or closed. With a small battery, it would work for years.
  178. Footprints: I had to make a footprint for this module on board package for one sensor. The solution to get footprints right? copy graphic image and make it into silkscreen on the board. Easy.
  179. The sensor I looked at was a temp and humidity sensor SHT11 (SHT10 is obsolete). It is low power enough. However, it's \$20. So not in my price range. Otherwise, it would work here. Looks like communication is a shift register, or SPI.
  180. \textcolor{green!60!blue!70}{
  181. \subsubsection{Magnetic Current Sensor}}
  182. There is this:
  183. BM14270AMUV-LB
  184. Which is low enough current here (<1mA). But \$7 in qty, and req's I2C. Not today.
  185. \textcolor{green!60!blue!70}{
  186. \subsubsection{Accelerometers}}
  187. These are an option.
  188. Best pinout (for deadbug) is LIS344ALHTR (but lacks vcc down to 1.8)
  189. 2nd Best pinout with full 1.8 -3.6 vcc is ADXL337BCPZ-RL7
  190. (Keep in mind, these are low end options only)
  191. (Analog output only. keep it simple for now.)
  192. Runner up to all above, is KXTC9-2050-FR . But has worse pinout.
  193. Going with AD part. \$5 in single qty.
  194. Digital output Accelmeters are cheaper.
  195. All have tiny package sizes.
  196. Since I am grabbing 1 output only, will need to orient or choose correct output.
  197. PINOUT: When I said best pinout, I meant that you can solder this by hand or with hot air, without much difficulty, because the layout does not require all pins to be connected (hoping I don't get bit by floating pins, though). Or, the layout has PWR and GND together, which means some pins can be bridged.
  198. \textcolor{green!60!blue!70}{
  199. \subsubsection{Temperature Sensors}}
  200. Temperature can be boring, but why not. Let's throw one of these on: LMT84LP . Pin compatible with LM35. Supply current is maybe 8uA. Extremely low.
  201. LM84 (1.5V starts, to 5.5), LM85 (1.8V to 5.5)
  202. \textcolor{green!60!blue!70}{
  203. \subsubsection{Gas Sensors}}
  204. Lowest is 5mV as of writing on dkey. Skipping. The SHT would work, but its too expensive.
  205. \textcolor{green!60!blue!70}{
  206. \subsubsection{Supercap}}
  207. For now, trying this:
  208. FG0V155ZF
  209. \textcolor{green!60!blue!70}{
  210. \subsubsection{Hall Effect Sensors - Push Pull vs Open Drain Outputs}}
  211. \begin{verbatim}9.1.1OutputTypeTradeoffsThe push-pulloutputallowsfor the lowestsystempowerconsumptionbecausethereis no currentleakagepathwhenthe outputdriveshighor low. The open-drainoutputinvolvesa leakagepaththroughthe externalpullupresistorwhenthe outputdriveslow.The open-drainoutputsof multipledevicescan be tied togetherto forma logicalAND.In this setup,if any sensordriveslow, the voltageon the sharednodebecomeslow. Thiscan allowa singleGPIOto measurean arrayofsensors
  212. \end{verbatim} From DRV5032 data sheet.
  213. \textcolor{green!60!blue!70}{
  214. \subsubsection{Conclusion: Starting Sensors}}
  215. So as a recap, to start with affordable, low power sensors for my project, I have the following types:
  216. \begin{itemize}
  217. \item Temp sensor (cheapest)
  218. \item Magnetic Sensor (hall effect)
  219. \item Movement Sensor (accellerometer) (analog output) (tiny package)
  220. \item capacitive sensor (azoteq)(may only be short range)
  221. \end{itemize}
  222. Output, I have not determined yet. IR will not work, as its too high power. Unless I dedicate a battery just for the IR diode... Or make it battery powered. I'll start with batteries, but for solar panel and supercap, it will likely not be viable, unless I transmit extremely rarely. That is also an option, however.
  223. \subsubsection{Farad to mA}
  224. 1.5F supercap can supply 1.5A for 1 second. That is 0.025A for 60 seconds, or 25mA for a minute.
  225. Let's stay I use half that, so 12mA for 60 seconds is my supply. If I transmit once every other hour (when in sunlight)...
  226. \subsection{PCB}
  227. I have built rev2 of the board today. Using an Uno, user must remember to include VCC and GND. So the programming takes up all 6 pins. The 0.1'' headers were slightly close to the resistors, and the top row of VCC and GND headers are separated, so I labeled them V+2, and GND2.\footnote{Forgetting to plug in GND, and or 5v+ (for Uno), while still plugging in the TPI pins, did not break the Attiny10, in my tests today.}
  228. The 0.05'' pin headers work perfect for scope probes. The extra breakout I made demonstrates this.
  229. \subsubsection{PCB Programming}
  230. By default, the Attiny10 idles around 1.5mA (5V), before programming.
  231. First thing to do, is to program it into a low power mode.
  232. In order to use low power, whilst using the Uno, I will need to add a jumper to the PCB,
  233. so that you can switch between V+2, and V+1. Three pin jumper. Outside pins are each V+, internal goes to Attiny V+. I'll need to remove the trace on gerber rev2, that goes from 4 to VCC.
  234. \subsubsection{PCB programming and use}
  235. It's not possible to leave the Arduino plugged in, while testing the Attiny10.
  236. example: Even if you power down the Uno, and use a jumper to change V+ rails,
  237. the power dissipation through the TPI pins (10,11,12,13) will cause a draw of about 545uA, and the Attiny10 will not toggle its led.
  238. Therefore, not only a power jumper is required to use the Attiny, but also
  239. a 4 or 5 pin 0.1" cable for the TPI pins, must be disconnected before using the Attiny.
  240. \footnote{In code section, mplab - tests2, the power draw of the 128KHz internal CLK with PB2 flipping at about 400us a cycle, at 3V VCC is about 115uA. At 2V it is ~95uA.}
  241. \subsubsection{PCB Rev3}
  242. \begin{itemize}
  243. \item Added jumper to switch between different power rails, so that
  244. Arduino can be left sort of plugged in (turns out, it is still required to disconnect 9,10,11,12,13 pins, so use a 4/5 pin cable). This makes testing low power (2-3V) code, easier, while still programming with the 5V Uno.
  245. \item Added SOT23-6 breakout
  246. \item Moved Resistors further from 9,10,11,12,13 pins.
  247. \item Added separate board for analog Accelerometer.
  248. \item Moved VCC breakout (0.5'' header pins) to connect directly to tiny, not to bottom Voltage rail.
  249. \item Added note about VCC and GND must be connected when programming.
  250. \item Added accelerometer pcb breakout. Package is small, but thanks to pinout/unused pins - is reasonable to solder with hot air. I knew this when I chose it... Then I forgot it earlier today.
  251. \end{itemize}
  252. \subsubsection{RF Comms}
  253. I want to use RF to communicate with this device. The IR would work, but would require batteries. If I'm going to use batteries I may as well use RF. Ideally, RF without batteries would be nice.
  254. I searched for LoRa modules, and came across this https://www.disk91.com/2015/technology/networks/first-step-in-lora-land-microchip-rn2483-test/
  255. I've added the datasheets. The RN2483 can be set with a UART, which means two pins on the Attiny. I will want to use a transistor to turn off the module (not using sleep mode), when not in use, so that's another pin. The 4th pin would be for whatever sensor I'm using. Right now, I'm thinking an accelerometer to watch for motion on a door or gate. I may need more pins, as I'd like to be able to switch the accel ic on and off as well.
  256. There is the Attiny40, and also an Attiny402. Different, but both worth considering. The Attiny40 is covered by my programmer, the 402 is not. 40 is from early 2010's, the 202/402 is from 2017. Also the Attiny20, which is less pins than the 40. But covered by my programmer. I would lean towards the 10 or the 20. 40 is too much IO.
  257. Attiny10 has I2C on board (TWI). I'm going to stick with the 10. Keep it simple.
  258. \subsubsection{Present Questions}
  259. questions:
  260. is a two pin UART the best I can expect to find for simple rf comms
  261. is lora a reasonable solution here? I want as low power as possible,
  262. Lora is not the lowest but if I transmit rarely, and for a short time perhaps it won't matter.
  263. Is there some other way to transmit data? I don't want to use ultrasonic waves, and IR seems to be too much current, as well
  264. as requiring line of sight / lens.
  265. \subsubsection{Plan of attack}
  266. I'm going to prototype with the Microchip RF modules for now, and see if I can get this working off a solar panel. I have an ADC, and with RESET disabled another IO. Goal is now:
  267. Configure RF modules w/arduino.
  268. Configure RF module (one Uno receiver, other tiny transmitter)
  269. Attach any sensor that uses ADC. (temp sensor, resistor light or thermocouple, current sensor (monitoring power supply), and I have the ones I already tested today (but will hold off on - the accelerometer, and hall effect).
  270. Desired applications
  271. - Temp of hot surface (boiler) monitoring
  272. - Solar current input monitoring.
  273. As I've already worked with a current sense before in my battery project (Electronics\_Projects\_2019), I will use again the INA169. It seems to be low enough power for my needs, though I will double check in practice. The data sheet lacks obvious power dissipation figures, while sensing, though quiescient is about 50uA.
  274. \subsubsection{Other Sensors}
  275. I need to verify that the following sensors could be used with low power:
  276. Light dependent Resistor / Diode
  277. Sound sensor (mic)
  278. \subsubsection{RF Searching}
  279. RF Transceiver ICs require assembly/programming/time, so we want RF Transceiver modules instead. There are a number of roughly 10mA TX active, but that is the lowest I can find. Among these ics (not modules), most are SPI, have their own ARM core... The modules are a bit better in having some that can be controlled by serial. I like the TRM-433-LT, but I will skip this for now (\$20 each).
  280. I also like the RC11xx-RC232, though the latter is about 30mA TX. That may be the best I can hope for. These two are 433MHz (ISM is 433 - 434MHz). The radiocrafts product is essentially a simplified solution, preprogrammed with a uart which can be used to adjust settings. This option appears to be on part with the microchip offering I've looked at, the RN2483, in fact they both came up on my search results, next to each other. RN doesn't have what IC they use but RC, uses CC1110.
  281. Another option:
  282. ZETAPLUS-433-SO is faster than others (500Kbs), and has lower TX (18mA). Up to 2KM range...
  283. There's more options (over \$18), but for the following specifications, the above three are basically what you can choose from. Ignoring those with high TX power rates (sparkfun), or requires SPI (stmicro)
  284. Specs:
  285. \begin{itemize}
  286. \item In stock
  287. \item Frequency 433-434MHz
  288. \item battery powered vcc range (2)
  289. \end{itemize}
  290. \footnote{There's only 25.}
  291. I will start with two Radiocraft modules. Let's see how that plays out.\footnote{A set of Dev boards for the radiocraft are \$250. Ouch.}
  292. \subsubsection{PCB Rev 5}
  293. \begin{itemize}
  294. \item Added instructions to back of board to speed up getting back to this project after some time.
  295. \item Moved resistors to be further away from programming header
  296. \item Fixed missed connection from JMP to V1 / V2 when I moved barrel plug, and added back the bottom right mounting hole in rev4.
  297. \item Changed prg/jmp/vcc to v1/jmp/v2 (either v rail can be used for programming)
  298. \end{itemize}
  299. \subsubsection{Input Protection on Accidental Reverse Cable Hookup}
  300. I'm going to want something to block plugging in the dupont cable backwards from breaking things. I had a square wave outputting on one pin of the Attiny10, and programming was going well, with the cable left in, until I removed, then connected it in backwards. The square wave blew something on the Atmega328p of the uno. This led me to quick replacement of the Uno atmega's here: electronics\_projects\_2020/AVRdragon\_Optiboot\_Atmega328
  301. I don't know what's better. Make it foolproof, or let people learn the hard way. With the latter, they at least get a way to reprogram blank Atmegas (quite useful with Unos).
  302. Perhaps instead, a mated connector would be enough on the breakout...
  303. \subsubsection{Nuts \& Volts 433MHz RF Transmitters}
  304. A recent nuts and volts issue (2019), covered a few sections on RF in one magazine. They covered, transmitters, as well as measuring power output of a transmitter (in separate articles). The RF transmitters they covered were 433MHz, ebay transmitters. The transmitters output the square wave you feed to them. Extremely basic. But also open to modifications and adaptations. The part count is very low, with minimal ICs. (The receivers do have an IC, though.)
  305. I've bought some of these, and will do some testing.
  306. \begin{center}
  307. \includegraphics[scale=1.5]{../pics/rxtx_433.jpg}
  308. \captionof{figure}{simple rx tx on 433mhz}
  309. \end{center}
  310. \subsection{Connecting to Programmer}
  311. These notes may be redundant, need to double check.
  312. When connecting, have a base setup that works as a sanity check.
  313. It may be possible to blow out atmega328p pins if you leave attiny running, thne
  314. plug in the cable back to front (i.e. pin 13 in 9).
  315. You might need to reboot the arduino completely.
  316. From Programmer Source code:
  317. - Upload to arduino and power off
  318. - Connect ATtiny10 as shown
  319. - Power on and open the serial monitor
  320. - If things are working so far you should
  321. see "NVM enabled" and "ATtiny10/20/40 connected".
  322. - Input one-letter commands via serial monitor:
  323. This programmer is not foolproof, so establish a routine, and keep a working
  324. model (pcb w/attiny) as a prototype to isolate what is broken.
  325. \subsection{Attiny10 Timer Fail}
  326. The goal was to get a 6KHz square wave out of the Attiny10 (first using the timer). After a night of trying to wrangle with timer 0 and CTC mode of the Attiny10 timer (which failed
  327. to work as expected). I've decided to buy a 6KHz oscillator. I was able to get 60.3KHz
  328. out of the Attiny using no optimization in mplab and IO as fast as possible. I was able
  329. to get 6.13Khz using optimization and a for loop (unfortunately the nops got optimized out).
  330. I also learned that the cable I was using to program the attiny10 was giving me much trouble.
  331. I ended up soldering one side to an uno. That out of the way, When programming the attiny10
  332. with my protoboard, it's as easy as, 1) connect cable to protoboard, 2) press P in serial monitor of Uno,
  333. 3) paste hex contents of mplab build into serial monitor. No need to ever reset the uno, even if
  334. it doesn't print that it detects the attiny. It's pretty good about this, and if connected
  335. correctly, will just write to the chip, when P is pressed.
  336. \subsection{Further Notes}
  337. https://www.eevblog.com/forum/microcontrollers/powering-devices-via-gpio-pins/msg2720044/\#msg2720044 - Using GPIO to power devices.
  338. leonerd TODO LINK HERE (bookmarks in main mach) attiny815 with rf. notice the coiled antennas
  339. https://www.eevblog.com/forum/beginners/rf-very-low-power-comms-simple/msg3016400/\#msg3016400 - Forum post regarding this project.
  340. \end{document}