 So, you also just launched DisplayPort 1.4? That's correct. DisplayPort 1.4 is the next generation of DisplayPort. It includes some additional features that people have been looking for. One is compression, which will let us do more displays, higher-resolution displays across the new Type-C connector. It also adds things for HDR, 8K at 60, that type of thing. So, the company that's sort of leading the way with compression is called Hardent. This is Stefan with Hardent, and he can tell you all about and actually show you how that compression scenario is going to work. So, what does Hardent do? Hardent was part of the development of the VISA standard for video compression, and a big manufacturer involved in the development of this standard. So, it reduces the data rate by over 50%. So, you do compression of what, and how, and where? Okay. We do compression using this algorithm, which is DisplayStream Compression, and this is a visually lossless algorithm. This means that when the picture is reconstructed, you cannot make visually the difference from the source one. So, here we have the source image, which is generated by the laptop. It goes through here an implementation of the encoder and decoder. They are in the same as a pattern called chip. This is FPGA SILENX development board, or what is this? It's just to demonstrate the functionality, but normally the encoder and decoder will be separately into different chip. So, it's like a chip that would be in where? In the display or in the device? Actually, it can be like in a mobile phone, and you will have the graphic processor that will encode the video and then transmit over a display port, for example, or the physical layer to the display part of the mobile device. So, here, what is shown here? The actual demonstration that we show you, there's the laptop generating the image, encoder and then decoding, and then you have the reconstruct output on the monitor. And we have split the screen into four different zones to show you what's going on. So, where is Harden base? Harden is base in Montreal, and as we were part of the standard development, it was a natural way for us to develop the IP, to be integrated into the chip manufacturer for the next generation of chip manufacturers. For example, Qualcomm has already integrated into their Snapdragon. Which one? I think the 820. So, the latest Snapdragon has your technology already? Yeah. So, that means they can output a whole bunch of 4K displays, what can they do? I don't know, it depends on their... Is it 3 4K and 2 8K, or how many is the maximum? Sorry, I'm joking. I can tell you the detailed spec of the Snapdragon, but they were an early adopter of the technology. And we're in touch with a lot of display and graphic chip manufacturers in Asia, also in Europe. What's the maximum with this technology? With compression, you can have more output, you can have several displays. What is it for? It can be, it's mainly, at first it was for a mobile device, because when you reduce the bandwidth, you compress by 3, then you reduce the power, which is used by the battery. You also reduce the power? Yeah, because when you do compression, you need less bandwidth to transmit the signal. So, this save power, this generate less noise into the device, and also has effect on the cost. On the other side, if you reduce by 3, then you can expand the resolution by 3 also, and have the same link. So, this allows to support 4K resolution, 5K and 8K, and our IP are scalable. So, this is really growing with the new trends of the industry. Two weeks before, the version 1.2 of the standard was released. Can you talk about which? Display port? No, of a display stream compression. So, you have version 1.2? Actually, it's 1.1, 1.2 was released two weeks ago. And the goal is to support the coding format by the HDTV and PC monitor. What format? Coding? The coding format, like they support 420, 422. And the goal is to provide the technology for the equipment manufacturer for TV, for PC monitor. So, this is also a market which will use our core. Another market is the automotive, because cars today integrate more and more display sensor camera. And they're looking into reducing the cabling into the car, the cost of the cabling. So, we have actually a car manufacturer evaluating our technology. Nice. We have less cable, it's less weight, it's more range. Everything's going to be better. That's awesome. Since when does your company do this kind of technology? Many years, we're also working with partners for telecommunication, networking and all those standards of Ethernet, but we have different expertise about the new trend of technology and we're mainly a design service company. So, people come to us when they have specific need that we have the expertise. And this was a natural way for us to go with video compression. And you're all based in Montréal? Yep. And it's called a... do you need a bunch of power to do the encoding, right? But that power is less than the transmission power of a higher bit rate file? You mean the chip that is... You said there was a power saving. Why the power? But you have to run the chip that encodes with your codec, right? Yep. And that power consumption is less than the transmission of a bigger file? Yep. For sure. But I can tell you the exact figure by how much is decreased compared to the chip power for doing the compression. But yeah, there's a saving, absolutely. Nice compression, that's cool.