What is TDP and why should you care about it?

Should you be looking at various parts to build a PC with, or to upgraded a specific component, you may have come across a term on your travels: TDP. But what exactly is TDP and why should you even care about the value provided by a manufacturer? We break everything down for you.

So, what is TDP?

TDP stands for Thermal Design Power, and is used to measure the amount of heat a component is expected to output when under load. For example, a CPU may have a TDP of 90W, and therefore is expected to output 90W worth of heat when in use. It can cause for confusion when shopping around for new hardware as some may take the TDP value and design a PC build around that, taking note of the watt usage. But this isn't entirely accurate, nor is it completely wrong.

Our 90W TDP CPU example doesn't mean the processor will need 90W of power from the power supply, even though thermal design power is actually measured in watts. Instead of showcasing what the component will require as raw input, manufacturers use TDP as a nominal value for cooling systems to be designed around. It's also extremely rare you will ever hit the TDP of a CPU or GPU unless you rely on intensive applications and processes.

The higher the TDP the more cooling will be required, be it in passive technologies, fan-based coolers or liquid platforms. You'll not be able to keep a 220W AMD FX-9590 with a laptop CPU cooler, for example.

TDP ≠ power draw?

Not quite, no. TDP doesn't equate to how much power will be drawn by the component in question, but that doesn't mean you can't use the value provided as an estimation. The reading itself is based on power so it can actually prove useful when looking at what you will need to provide enough juice. Generally, a component with a lower TDP will need draw less electricity from your power supply.

Actual readings listed by manufacturers can vary as well, depending on their own findings. So while the value of TDP may not exactly reflect how much power a part will draw in a system, it does provide solid grounds to design a cooling system around it, as well as a rough idea as to how much output a power supply (PSU) will need to have. To be safe, we usually recommend a quality brand PSU of 500W for a PC with a single GPU.

Conclusion

If that still has you flabbergasted with TDP, it's essentially a reading that helps determine the power efficiency and performance of a component. Using a CPU as an example, one with higher TDP will usually provide more in terms of performance, but will draw more electricity from the PSU. TDP is not — however — a direct measure of how much power a component will draw, but it can be a good indicator.

Be sure available cooling you have at hand is more than enough to keep components cool, especially when it comes to the GPU and CPU.

So What's the laptop cooling construction likes, defined what's your TDP can be.

For small laptop, how to solved the heat dissipation issue to make cooling system to reach the good TDP, it's a big problem.

Now GPD was find the balance, they launched the smallest ultrabook GPD P2 MAX, just 8.9" but use the 15w TDP on m3-8100y, that's really awesome.

Also it's has 16GB DDR3+512GB SSD, but only $700, now live on INDIEGOGO.

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What is PPI: Pixels Per Inch, Display Resolution

PPI stands for Pixels Per Inch and is a metric typically used to describe the pixel density (sharpness) for all sorts of displays, including cameras, computers, mobile devices, etc… It is important to understand what it really means in a world where visual computing and visual quality has increased exponentially over the past decade, and where PPI has become a prime marketing tool.

PPI is an interesting metric, but it cannot be used by itself as a sharpness benchmark because the distance between our eyes and the display is as important as the pixel density itself. If you bring your screen closer to your eyes, you will see the pixels. If you move the device further away, the additional pixel density may not be useful at all, because it won’t be perceptible. Smartphones are used much closer to your eyes than tablets. Computer monitors are a little further away and TV, cinema screen etc are even farther. Because of that, they require different PPIs to achieve the same perceived sharpness from your point of view.

What 20/20 vision really means?

Let’s look at how human visual acuity is measured: we have all heard of “20/20 vision”, and it would make sense to think that it means “perfect” or “maximum” vision, but that’s not true at all. The 20/20 vision test comes from the Snellen chart (on the right), which was invented in 1860 as a mean to measure visual acuity for medical purpose. This is important because Snellen was trying to spot low-vision, which is a medical problem. No medical patient has ever complained of having above-average visual acuity.

20/20 vision actually means that you have “normal” vision, which assumes that “most” human can achieve reading all the letters in the chart at a distance of 20 feet (about 6 meters or yards). In short, 20/20 really means “average” vision. People with poor vision will only be able to read the top row of letters at 20 feet, while most of the population can read them at a much greater distance.

The 300 PPI “myth”

The 300 PPI limit is just marketing.

You may have heard many times that the human eye cannot distinguish details beyond 300 PPI. We have heard that for years when discussing Print work, and recently, the launch of the iPhone 4 moved that same myth into the mobile world.

The previous paragraph is key to understanding the 300 PPI claim that was made when the iPhone 4 came to the market. Apple’s CEO Steve Jobs implied on stage that the human eye could not perceive sharpness beyond 300 PPI in the context of Smartphone usage.

Steve Jobs considered that you are holding your phone/tablet at 10-12 inches from your eyes. There was a lot of controversy, but astronomer Phil Bait wrote a good article saying that it depends on how you look at it. He has a less polarizing opinion than many of the articles that came out at the time.

Mr. Jobs’ 300 PPI claim maybe remotely true only if you use the 20/20 vision as a reference. But the (big) caveat is that 20/20 vision does not represent “perfect” vision, not by a long shot. Real human vision limits are actually much higher than that – possibly closer to 900 PPI or more depending on who you talk to. Research from Sun Microsystems estimated the limit to be at least 2X what 20/20 vision is (pdf link), and Sharp thinks that humans can see up to 1000 PPI (pdf link).

No scientific consensus, but research points to higher sharpness limits

The limits of human vision are still under intense research, but just like other human physical activities, there is such an upper limit that would apply for the large majority of the population. But first, it’s necessary to understand how visual acuity is measured from your eye’s point of view. The most common metric that we have seen is the “arc minute” or “minute of arc”.

Arc minutes measure the size of things we see in terms of visual angle. This is convenient because it allows to express the size of things as perceived by our eyes, without regards to where they are in space. Some have proposed using a metric that may seem easier to grasp: pixels per (visual) degree. In that metric, 20/20 vision would be more or less equivalent to 58 pixels per degree of vision. Sony cites that NHK research has measured human visual acuity to 312 pixels per degree while research from NASA mentions 0.5-1.0 arc minutes

While there is no definitive answer to the question, most research points to the fact that 300 PPI does not represent the human visual acuity limit in the context of Smartphonee displays.

How Higher PPI may benefit you (or not)

Since the initial emergence of high DPI displays with the iPhone 4, we know from experience that the human eye can see beyond those 300 DPIs. How far we will go remains to be seen, and we would agree that there is a point of diminishing returns.

In the end, it depends on your own vision: in our experience, most people who own Smartphones that have a PPI higher than 300 can perceive that there is a difference in sharpness. That is especially true when looking at nature scene photos or simply text and icons.

What’s important is that you understand that perceiving details beyond 300 PPI is not some kind of super-human feat, a gift of nature to a few of us. Chances are that you are able to see much more detail than what the 20/20 chart was intended to measure in 1860.

Finally, the level of details that a display can output is not only about what we can pay attention to. Japan’s NHK Researchers point out that smaller pixels and more details are making the overall image look much more real. That’s probably why many people say that 4K TV seems more “real” than 3D TV.

Anyway When this concept was mentioned out, the means it's could be exist.

Now GPD adhering to the Jobs's concept, on their latest products the smallest ultrbook GPD P2 Max, they made the PPI to 340, would be keep user experience to top.

8.9 inch size but with active cooling system to handle the M3-8100y with 16GB RAM and 512GB SSD, but just $700.

Now it's live on INDIEGOGO.

USB Type-C Explained: What is USB-C and Why You’ll Want it

USB-C is the emerging standard for charging and transferring data. Right now, it’s included in devices like the newest laptops, phones, and tablets and—given time—it’ll spread to pretty much everything that currently uses the older, larger USB connector.

USB-C features a new, smaller connector shape that’s reversible so it’s easier to plug in. USB-C cables can carry significantly more power, so they can be used to charge larger devices like laptops. They also offer up to double the transfer speed of USB 3 at 10 Gbps. While connectors are not backwards compatible, the standards are, so adapters can be used with older devices.  

Though the specifications for USB-C were first published in 2014, it’s really just in the last year that the technology has caught on. It’s now shaping up to be a real replacement for not only older USB standards, but also other standards like Thunderbolt and DisplayPort. Testing is even in the works to deliver a new USB audio standard using USB-C as a potential replacement for the 3.5mm audio jack. USB-C is closely intertwined with other new standards, as well—like USB 3.1 for faster speeds and USB Power Delivery for improved power-delivery over USB connections.

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Type-C Features a New Connector Shape

USB Type-C has a new, tiny physical connector—roughly the size of a micro USB connector. The USB-C connector itself can support various exciting new USB standard like USB 3.1 and USB power delivery (USB PD).

The standard USB connector you’re most familiar with is USB Type-A. Even as we’ve moved from USB 1 to USB 2 and on to modern USB 3 devices, that connector has stayed the same. It’s as massive as ever, and it only plugs in one way (which is obviously never the way you try to plug it in the first time). But as devices became smaller and thinner, those massive USB ports just didn’t fit. This gave rise to lots of other USB connector shapes like the “micro” and “mini” connectors.

This awkward collection of differently-shaped connectors for different-size devices is finally coming to a close. USB Type-C offers a new connector standard that’s very small. It’s about a third the size of an old USB Type-A plug. This is a single connector standard that every device should be able to use. You’ll just need a single cable, whether you’re connecting an external hard drive to your laptop or charging your smartphone from a USB charger. That one tiny connector is small enough to fit into a super-thin mobile device, but also powerful enough to connect all the peripherals you want to your laptop. The cable itself has USB Type-C connectors at both ends—it’s all one connector.

USB-C provides plenty to like. It’s reversible, so you’ll no longer have to flip the connector around a minimum of three times looking for the correct orientation. It’s a single USB connector shape that all devices should adopt, so you won’t have to keep loads of different USB cables with different connector shapes for your various devices. And you’ll have no more massive ports taking up an unnecessary amount of room on ever-thinner devices.

USB Type-C ports can also support a variety of different protocols using “alternate modes,” which allows you to have adapters that can output HDMI, VGA, DisplayPort, or other types of connections from that single USB port. Apple’s USB-C Digital Multiport Adapter is a good example of this, offering an adapter that allows you to connect an HDMI, VGA, larger USB Type-A connectors, and smaller USB Type-C connector via a single port. The mess of USB, HDMI, DisplayPort, VGA, and power ports on typical laptops can be streamlined into a single type of port.

USB-C, USB PD, and Power Delivery

The USB PD specification is also closely intertwined with USB Type-C. Currently, a USB 2.0 connection provides up to 2.5 watts of power—enough to charge your phone or tablet, but that’s about it. The USB PD specification supported by USB-C ups this power delivery to 100 watts. It’s bi-directional, so a device can either send or receive power. And this power can be transferred at the same time the device is transmitting data across the connection. This kind of power delivery could even let you charge a laptop, which usually requires up to about 60 watts.

Apple's new MacBook and Google's new Chromebook Pixel both use their USB-C ports as their charging ports. USB-C could spell the end of all those proprietary laptop charging cables, with everything charging via a standard USB connection. You could even charge your laptop from one of those portable battery packs you charge your smartphones and other portable devices from today. You could plug your laptop into an external display connected to a power cable, and that external display would charge your laptop as you used it as an external display — all via the one little USB Type-C connection.

There is one catch, though—at least at the moment. Just because a device or cable supports USB-C does necessarily mean it also supports USB PD. So, you’ll need to make sure that the devices and cables you buy support both USB-C and USB PD.

USB-C, USB 3.1, and Transfer Rates

USB 3.1 is a new USB standard. USB 3‘s theoretical bandwidth is 5 Gbps, while USB 3.1’s is 10 Gbps. That’s double the bandwidth—as fast as a first-generation Thunderbolt connector.

USB Type-C isn’t the same thing as USB 3.1, though. USB Type-C is just a connector shape, and the underlying technology could just be USB 2 or USB 3.0. In fact, Nokia’s N1 Android tablet uses a USB Type-C connector, but underneath it’s all USB 2.0—not even USB 3.0. However, these technologies are closely related. When buying devices, you’ll just need to keep your eye on the details and make sure you’re buying devices (and cables) that support USB 3.1.

Backwards Compatability

The physical USB-C connector isn’t backwards compatible, but the underlying USB standard is. You can’t plug older USB devices into a modern, tiny USB-C port, nor can you connect a USB-C connector into an older, larger USB port. But that doesn’t mean you have to discard all your old peripherals. USB 3.1 is still backwards-compatible with older versions of USB, so you just need a physical adapter with a USB-C connector on one end and a larger, older-style USB port on the other end. You can then plug your older devices directly into a USB Type-C port.

Realistically, many computers will have both USB Type-C ports and larger USB Type-A ports for the immediate future—like Google’s Chromebook Pixel. You’ll be able to slowly transition from your old devices, getting new peripherals with USB Type-C connectors. Even if you get a computer with only USB Type-C ports, like Apple’s new MacBook, adapters and hubs will fill the gap.

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USB Type-C is a worthy upgrade. It’s making waves on the newer MacBooks and some mobile devices, but it’s not an Apple- or mobile-only technology. As time goes on, USB-C will appear in more and more devices of all types. USB-C may even replace the Lightning connector on Apple’s iPhones and iPads one day. Lightning doesn’t have many advantages over USB Type-C besides being a proprietary standard Apple can charge licensing fees for. Imagine a day when your Android-using friends need a charge and you don’t have to give the sorrowful “Sorry, I’ve just got an iPhone charger” line!

Now Smallest Ultrabook GPD P2 Max has full function USB-C.

That means you might just need a HUB, then you can complete all you want. Charging, data transporting, RJ45, 4K decoding, anything just you can imaging.

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