The Powers of Induction Log
Week of 1/22
This week we decided to change the direction of our project. Instead of creating optical character recognition software, we decided to instead build an wireless charger for mobile smart devices. We are planning on creating a stand for an iPad that allows the user to charge while watching videos or surfing the web.
Week of 1/29
We met on Tuesday, brushed up on some electrical engineering basics, and learned about the underlying principles behind inductive power transfer. We learned that iPads and iPhones do not contain receiver coils, but instead require an additional adapter to be able to receive power from an inductive charger. Many smart phones created by another companies such as Samsung do contain receiver coils. We decided to build a charging pad that will work with compatible smart phones. In addition, we decided to design and 3D print an iPhone case that contains an adapter so that audience members at the demo can try out the charger even if they have an iPhone.
Week of 2/5
Blake met with Andrew on Monday and researched Wireless Power transfer and the Qi standard for wireless charging. In addition, he watched a few tutorials on MultiSim, the circuit simulation software available in the ESE Teaching Lab. Elizabeth watched tutorials on AutoCAD and researched circuit design. In light of the feedback from our proposal last week, we are considering changing the priorities of our project and what our demo will look like. There may not be enough information for us to reliably design a charging station that will be compliant with the Qi adapter used by iPhones. We also need to specify our goals in more depth. What are the elements of our design that we really care about? It's likely that our current proposal lacks focus and sufficient detail. Instead of charging stranger's phones (which comes with the additional liability of damage), we are considering having our device charge something besides phones.
Week of 2/12
We met separately from Andrew to discuss the focus of our project and came to a better understanding of what we're trying to do. Our modified goal is to output charge to a wireless port instead of the more finicky Qi adapter. Elizabeth made a circuit diagram, and Blake worked on the design and refined the budget based on design changes. We both learned the functions of the various parts required for our design. We met with Andrew on Monday and explained our new focus then rewrote our Wiki page with our new information in mind. Our project seems more set in stone and realistic now that we have the details decided, and we are ready to order our parts as soon as it's approved.
Week of 2/20
On Monday, Blake continued trying to get a simple simulation to work on MultiSim. For some reason, the current and voltage coming out of the drain of the MOSFET was much lower than the supply side voltage. He varied the frequency of the pulsing gate source (which is standing in for the Arduino) to no avail. He fiddled with it and is now considering using an amplifier to increase the magnitude of the switching voltage on the drain side of the MOSFET. That way the magnitude of the voltage can be manipulated while the temporal frequency of the switching is preserved. Additionally, there are no bridge rectifier (although it was easy to construct a diode bridge with 4 diodes) or 7805 Voltage regulators easily available on MultiSim so it is difficult to test the validity of anything he's doing. In addition, he tried varying the coupling coefficient between the inductors to see if that made any impact. Perhaps he simply grounded something he shouldn't have. More to come.
