 Okay, so what we're demoing here is our ST25R3911B discovery board. So our reader chip has three very unique features. Number one is output power. We have up to 1.4 watts of output power. What this equates to is read range. So you can see here that I'm reading a 15693 card at about 17 centimeters. A 14443A card at about 14 centimeters. And this is all with a standard size antenna. So more output power, more rearrange. We have high output power, but we also have a way to control that. So you're not burning excess power, especially when you're battery operated. So if we go to wake up, here what we're doing is we're measuring the two, or the dielectric between the two capacitive pads that we've laid out on the board. This requires no external components. And essentially we can monitor this. And in this mode we're only drawing four microamps of current. So if anything comes between those two pads and changes the dielectric, we generate an interrupt, which wakes up a microcontroller, which allows us to do a tag read. So once again, this is all self-contained, no external components needed. And finally, we have auto antenna tuning. So anything metal will detune your antenna, which will decrease your read range. So I can demonstrate this by taking my phone and putting it on here. And you can see how the antenna gets detuned both in phase and magnitude. However, if I put continuous auto-adjust, so now we're always monitoring the antenna to make sure that we have maximum power being delivered. If I take my phone and put it on there again, you'll see that the magnitude stays relatively the same along with the phase. So this ensures that we're delivering the most amount of power that we can for the tag. So for tags that require energy harvesting, we're going to ensure that we're providing the maximum amount of power for that.