A few months back I was informed by a key house member that the Lab was getting a little out of hand and that parts had to stop coming in and had to start leaving.\u00a0 Thus began \u201cOperation Get Rid of Stuff\u201d, which commenced with a simple project: building a light.<\/p>\n
![\"The](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/IMG_2440.jpg\" "\\"The")
<\/a>Jonathan’s Corner, a.k.a “The Laboratory”<\/p><\/div>\n
The back of our house had no exterior lights, which made unlocking the back door at night a challenging endeavor to say the least.\u00a0 We intended on purchasing some kind of exterior light when it occurred to me that I had more than enough parts laying around to build a solar powered light.\u00a0 With proper hacks to an old PCB, I could make it work.<\/p>\n
This PCB was an circuit that I had made for some friends a while back to learn how to solder and do some basic C programming.\u00a0 It wired four buttons and four seven segment displays (SSD) to a PIC18F14K22 processor, with a solar lithium polymer charging circuit.\u00a0 I luckily had two PIC18s, a few buttons, SSDs, and a spare 0.5W solar panel.\u00a0 All I needed was to create a small daughter board for white LEDs (which I also had collecting dust) and somehow solder it on the main PCB to make it a fully functional solar light.<\/p>\n
<\/a>PCB to hack.<\/p><\/div>\n
Although this project was done using an old PCB, it could easily be wired on a breadboard.\u00a0 The parts required to do this are:<\/p>\n
- \n
- A PIC18F14K22 (great little PICs by the way).<\/li>\n
- A BCD to Seven Segment Display (SSD) Decoder: something like a 74HC4511.\u00a0 I luckily found in surplus (and thus for cheap) MC14543B, which are BCD to SSD ICs with fancy LED driving circuitry and latching inputs.\u00a0 On Semiconductors<\/a> actually still make these; they make for great for any simple SSD based projects.<\/li>\n
- 5V solar cells.\u00a0 Sparkfun<\/a> sells a really nice 0.5W that is terminated with a barrel plug.<\/li>\n
- A Lithium Polymer (LiPo) battery.\u00a0 You can find some once again at Sparkfun<\/a>.<\/li>\n
- The MAX1555 Lithium Polymer Charger (a very nice, cheap charger in SOT23-5).\u00a0 Sparkfun<\/a> sells an adapter such that the part can be placed on a breadboard.<\/li>\n
- A momentary push button.<\/li>\n
- At least two Seven Segment Displays.<\/li>\n
- A whole bunch of 330Ohm resistors.<\/li>\n
- About six white LEDs.<\/li>\n
- One 4.7K-10KOhm resistor.<\/li>\n
- Five 10k-1MOhm resistors.<\/li>\n
- Two 1uF capacitors.<\/li>\n
- Two 0.1uF capacitors.<\/li>\n
- A PMOS (or, preferably, a NMOS).<\/li>\n
- Four NMOSs.<\/li>\n
- (Optional) A red LED and a switch.<\/li>\n<\/ol>\n
The schematic for the solar battery charger is pretty simple, and uses the extremely handy MAX1115 Lithium Polymer charger IC.\u00a0 For real simple charging, the MAX1555 can’t be beat.<\/p>\n
![\"5V](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/Solar-Light-Lipo-Charger-1024x287.png\" "\\"Solar")
<\/a>5V Solar Lithum Polymer charging circuit.<\/p><\/div>\n
Wire the 5V solar panel straight into the MAX1555 DC input, the battery to the BAT output, and voil\u00e0, you are charging a battery (doesn’t get easier than that)!\u00a0 The red LED is optional: whenever the MAX1555 is actively charging the battery, it will pull down the CHG’ signal, thus turning on the LED.\u00a0 Note that if you are building this circuit for yourself, you will want the ability to switch off the LED (hence the switch in the schematic): otherwise, a great deal of energy used to charge the battery will instead go to the LED.<\/p>\n
The SSD display portion of the PCB uses the MC14543B to convert a BCD value to its corresponding SSD representation.\u00a0 The MC14543B is designed to run a variety of SSD displays (including LCDs) and has latching inputs, although they are all disabled on the schematic.\u00a0 Really, a 74HC4511 could have been used.<\/p>\n
![\"SSD](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/Solar-Light-SSD-Display-1024x265.png\" "\\"Solar")
<\/a>SSD Display<\/p><\/div>\n
The outputs of the MC14543B are wired to all four SSDs, and in turn each SSD’s COM pins are wired to an NMOS.\u00a0 The NMOSs are controller by the PIC18, which turns one of them on one at a time, in sequence, and very quickly.\u00a0 Whenever the NMOS is OFF, the LEDs for said SSD are off.\u00a0 If the NMOS is on, the corresponding segments of the SSD are turned on in function of the BCD value on the LA, LB, LC, and LD signals.\u00a0 As such, each SSD can display a separate and unique value, using only one BCD to SSD IC.\u00a0 The values for the resistor tied to the NMOSs’ gate (R2-R8) are pretty arbitrary, and given the generally slow strobe speed of the SSD display, don’t really matter.<\/p>\n
The SSD display, along with a single button,\u00a0 are connected to the PIC18.\u00a0 No magic here.\u00a0 Notice that the 4.7KOhm resistor used for the ICSP can be any value between 1K to 10K, according to Microchip.<\/p>\n
![\"PIC18](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/Solar-Light-Processor.png\" "\\"Solar")
<\/a>PIC18 connections to the remainder of the schematic.<\/p><\/div>\n
The light functions as follows:<\/p>\n
- \n
- The circuit is initially off and in a low power mode (all lights are off, and the processor is in sleep mode).\u00a0 This allows the maximum amount of energy from the sun to charge the battery during the day.<\/li>\n
- When night falls, and we need light, I press the lone button populated on the PCB.<\/li>\n
- The button press activates the white LEDs for 15 seconds.\u00a0 Subsequent button presses add another 15 seconds to the total time, and the time counts down to zero.\u00a0 The time is shown on the SSD display.<\/li>\n
- Once the elapsed time expired (i.e. the countdown reaches zero), the circuit returns to a low power state, and the LEDs turn off.<\/li>\n<\/ol>\n
First, I built the white LED daughter board.\u00a0 I had a logic level TO-220 30V PMOS lying around which I used to power on the LEDs (I would have preferred using an NMOS, but I had none at the time.\u00a0 I have since addressed the issue, to some household members’ dismay).\u00a0 The schematic is very similar to the NMOS schematic used on the SSD display.<\/p>\n
![\"White](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/Solar-Light-Lights.png\" "\\"Solar")
<\/a>White LED daughter board schematic.<\/p><\/div>\n
![\"Front](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/IMG_2430-225x300.jpg\" "\\"Front")
<\/a>Front side of white LED daughter board.<\/p><\/div>\n
![\"Back](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/IMG_2431-225x300.jpg\" "\\"Back")
<\/a>Back side of white LED daughter board.<\/p><\/div>\n
Much like the NMOSs, the 1MOhm and the 330Ohm resistors values can be changed because we have no speed requirement for turning the PMOS on\/off (the astute observer will notice that the values on the back side of the daughter board are actually different).\u00a0 The ballast resistor for the white LEDs (R21) is selected such that at 5V, every LED gets around 10mA.\u00a0 In an ideal world, each LED would share current equally.\u00a0 In reality, however, LEDs tend to have poor I-V characteristics (even in LEDs from the same production batch), which leads them to not share current equally (more on this later).\u00a0 For this project, I don’t really care, but in some applications this can be a big deal.<\/p>\n
I then wired the daughter board on the PCB and soldered the PIC, the BCD-SSD IC, the button, and the four SSDs to the PCB.<\/p>\n
After a little bit of C code for the PIC18, I had a completed project.<\/p>\n
![\"Project](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/IMG_2432-1024x768.jpg\" "\\"Completed")
<\/a>Project Complete!<\/p><\/div>\n
That little red PCB on the upper left of the green PCB is a 5V boost converter built by Sparkfun<\/a>.\u00a0 Fantastic little thing, and well worth the price.\u00a0 It’s not needed for this project, but I only had a -5V Vgs(th) PMOSs available at the time, too large a value for the LiPo’s voltage to fully turn the PMOS on.\u00a0 Boosting the voltage to 5V solves this issue.\u00a0 To save on cost, I would instead recommend getting a smaller Vgs(th) PMOS and running this project unregulated (as shown in the schematic).\u00a0 Yes, the white LEDs will progressively dim as the battery voltage slowly drops, but the underlying battery life will be greatly increased.<\/p>\n
Since this thing had to go outside and survive that harsh suburban wilderness, I couldn’t leave the circuit exposed in such a fashion: any kind of precipitation would effectively destroy the project (and my morale) in seconds.\u00a0 So I looked through the scrap pile and found a heavily damaged (but useable) clear acrylic project box.\u00a0 It had a hole in it, but I could enlarge it to let the button to poke through.\u00a0 It took a bit of finagling and lots of electrical tape to get it in there, but it fit.<\/p>\n
![\"Ugly](\"http:\/\/www.teracharge.com\/wp-content\/uploads\/2012\/10\/IMG_2433-1024x768.jpg\" "\\"Ugly")
<\/a>Ugly boxing job, but hey… it works!<\/p><\/div>\n
I used some leftover weight bearing rope to hang the light from a nail on the wall.\u00a0 It\u2019s now been happily hanging by our door and gets daily usage.\u00a0 It will be interesting to see how the light will function in winter, given the shorter days and the harsher LiPo operating temperatures.<\/p>\n
- 5V solar cells.\u00a0 Sparkfun<\/a> sells a really nice 0.5W that is terminated with a barrel plug.<\/li>\n