Which do you prefer: 1080p or Quad HD screens? (Poll of the Week)

Last week’s poll summary: Last week, we asked you which is the better battle royale game: PUBG or Fortnite. Out of over 48,000 total votes, roughly 65 percent of voters on Facebook and Instagram said they prefer PUBG. On the website, YouTube, and Twitter polls, about 45 percent said they prefer PUBG over Fortnite, while many folks said they don’t care for either game. Check out the full polling results here.


The LG G3 was one of the first phones with a Quad HD screen. Since the first time I saw it in real life, I was hooked. 1080p screens just couldn’t do it for me anymore.

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Yeah, I know — unless you’re really looking, it’s hard to tell the difference between a Full HD display (1920 x 1080) and a Quad HD (2560 x 1440) one. But to me, the display is one of the most important aspects of the phone. It’s the one component that you stare at every day. If your phone has a bad screen, you’re going to notice it every single day.

After a few years of fawning over those high-res screens, though, I’ve since come around to the idea of sporting a 1080p display. After all, the phone doesn’t have to power as many pixels, which oftentimes results in better battery life.

Which do you prefer: Full HD screens or Quad HD screens? Are you willing to sacrifice battery life for a better looking display, or are you just fine with a 1080p panel? Cast your vote in the poll below, and speak up in the comments if you have anything to add.

Note: There is a poll embedded within this post, please visit the site to participate in this post’s poll.
Source: Android Zone

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How fast charging really works

Fast Charging plugs compared

Fast charging is a must have feature in today’s phones. It keeps our batteries topped up through busy days. However, there are a variety of different standards from different companies. Some only work with specific cables and chargers, while others use higher voltages. It can all get a bit confusing, so we’re here to make sense of it.

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In a nutshell, fast charging increases the current sent to the battery to fill up its capacity quicker. The basic USB specification only sends 0.5 amps (A) of current using 5 volts (V) for just 2.5 watts (W). Fast charging technologies boost these figures. Huawei’s 5V/5A SuperCharge produces 25W and Samsung’s 9V/1.7A Adaptive Fast Charging produces 15W of juice. All fast charging services share a — more power.

That’s just the basic overview. How a battery actually charges up is more complicated. Before we get to that, let’s look at the differences between all of these fast charging standards in more detail.

Fast charging standards explained

USB Power Delivery

USB Power Delivery (USB-PD) is the official fast charging specification published by the USB-IF back in 2012. The standard can be used by any device with a USB port, provided its manufacturer includes the necessary circuitry and software. Just like all fast charging standards, USB-PD implements a data protocol to communicate between the charger and phone. This negotiates the maximum tolerable power delivery for both the charger and handset.

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USB Power Delivery augments the basic USB charging speeds for up to 100W of output power. The amount of available power is split into different power ratings, which operate at different voltages. The 7.5W+ and 15W+ modes are best for phones, while 27W and above are for laptops and other higher power devices. The standard also supports bi-directional power, enabling your phone to charge other peripherals.

Power output
(Operating Voltage and Current)
0.5 – 15W 15 – 27W 27 – 45W 45 – 60W 60 – 100W
5V 0.1 – 3.0A 3.0A (15W cap) 3.0A (15W cap) 3.0A (15W cap) 3.0A (15W cap)
9V 1.67 – 3.0A 3.0A (27W cap) 3.0A (27W cap) 3.0A (27W cap)
15V 1.8 – 3.0A 3.0A (45W cap) 3.0A (45W cap)
20V 2.25 – 3.0A 3.0 – 5.0A

Google’s Pixel series utilizes the official Power Delivery specification. Apple also implements the standard in the iPhone 8, iPhone X, and latest MacBooks. Many companies prefer their own proprietary charging standards.

Qualcomm Quick Charge

Qualcomm’s proprietary Quick Charge technology was once the default standard in the smartphone industry, as it popularized fast charging before USB Power Delivery. The latest 4.0+ revision of Quick Charge is compatible with Power Delivery, allowing for faster-charging speeds and a wider range of support.

  Voltages Max Current Max Power
Quick Charge 1.0 5V 2A 10W
Quick Charge 2.0 5 / 9 / 12V 3A 18W
Quick Charge 3.0 3.6 – 20V (200mV increments 2.5 / 4.6A 18W
Quick Charge 4.0+ 3.6 – 20V (200mV increments) QC Mode
5 / 9V USB-PD Mode
2.5 / 4.6A QC Mode
3A USB-PD Mode
18W QC Mode
27W USB-PD Mode

Quick Charge is an optional feature available with Qualcomm’s Snapdragon processors. So just because a phone has a Qualcomm chip doesn’t mean it is Quick Charge compatible. Even so, a wide range of phones boast Quick Charge support, including the LG V30, LG G7, Samsung Galaxy Note 8, HTC U12 Plus, and many more. There’s also a broad ecosystem of legacy chargers and third-party accessories out there, due to the standard’s popularity.

A charging dongle shows the amount of current passing to a fully charged smartphone

Other standards

In the smartphone ecosystem, many models use in-house technologies rather than the more ubiquitous standards above. However, only a few of these standards are truly proprietary. Many are just Power Delivery or Quick Charge repackaged under a different brand name, or featuring some specific tweaks to the technology — Samsung’s Adaptive Charging and Motorola’s Turbo Charging technologies come to mind.

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Others like Oppo’s VOOC and Huawei’s SuperCharge operate quite differently. These greatly increase the amount of current for high power charging rather than increasing the voltage. Here is how some of the most common technologies stack up side by side.

Charging Technology USB 2.0 port USB 3.0 port Samsung Adaptive Fast Charger OnePlus DashCharge / Oppo VOOC Huawei SuperCharge MediaTek PumpExpress 4.0
(USB-PD)
Motorola TurboPower 30
(USB-PD)
Max Power 2.5W 7.5W 15W 20 / 25W 25W ~25W 28.5W
Voltage 5V 5V 5V / 9V 5V 5V 3V – 6V
(10-20mV per step)
5 / 9 / 12V
Current 0.5A 0.9 / 1.5A 2 / 1.67A 4 / 5A 2 / 4.5 / 5A 5A 5.7 / 2.85 / 2.15A

It is possible to support multiple standards or at least ensure some level of compatibility with different fast charging methods. Unfortunately, this leads to a lot of unpredictability about the exact charging speeds you’ll receive when using phones with different chargers and even different cables.

After testing several phones, we found a wide variation in how much power each phone negotiated, depending on the charger and cable used. The best results are typically achieved by using the cable and charger supplied in the box with your handset.

How to fast charge a Lithium-ion battery

Now that we’ve covered the standards, let’s delve into how fast charging actually speeds up a battery’s charging cycle. Lithium-ion batteries used inside smartphones and other electronic gadgets don’t charge in a linear fashion. The charging cycle is broken into two distinct phases.

The first is the increasing voltage, or constant current phase. The battery voltage steadily increases from as low as 2V up to its peak of around 4.2V as it charges up. This varies depending on the exact battery. The battery draws the highest peak current during this phase, which remains constant until the battery voltage peaks.

The voltage then becomes constant and the current begins to fall. Batteries that charge beyond this point draw less current and therefore charge slower. This is why the first 50 or 60 percent of your phone charges considerably faster.

Graph of battery charging voltages

Battery University Battery charging occurs in two phases. Rising voltage/constant current and constant voltage/falling current. The first phase is suitable for high-current fast charging.

Fast charging technologies exploit the constant current phase. Pumping as much current as possible into the battery before it reaches its peak voltage. Therefore, fast charging technologies are most effective when your battery is less than 50 percent full, but have little to no effect as you pass 80 percent. Incidentally, constant current charging is the least detrimental period to the battery’s long-term health. Higher constant voltage, along with heat, is detrimental to battery life.

Finally, the amount of voltage and current passed to the battery is controlled via a charge controller circuit inside the phone. Coupled with temperature and voltage sensors, the controller can manage the amount of current to optimize the battery’s charge speed and long-term health.

Fast charging at high voltage?

Some of you may have spotted an apparent issue here. If lithium-ion batteries have a typical voltage around 3 to 4.2V, isn’t it dangerous to use higher voltage chargers?

Ordinarily this would be the case, but smartphone circuits step voltage down and current up. This keeps the amount of power transferred the same (P = IV), but moves the voltage into the correct range. And no, fast charging cables don’t do AC voltage conversion. If you look on the back of the charger, you’ll be able to spot the little dashed DC current icon ⎓. USB is always a DC power delivery system.

High voltage fast charging circuits use a switch-mode step-down power supply, also known as a buck inverter. This circuit takes a high DC voltage and converts it down to a lower DC voltage. Ideally, it also multiplies the current by the inverse amount thanks to its “charge pump” characteristics. It’s essentially a switch toggling the input voltage to charge up a capacitor with lots of current.

Buck Converter topology and waveform diagram

Analog This looks complicated, but follow the graphs on the right. The high input voltage switches on and off to create a PWM signal from Vin. This induces a high “pumping” current through the inductor L into capacitor Cout. At the load (battery) we see a high current and low average voltage (Vout).

Stepping down from 10V/1A to 5V ideally yields 2A current after the converter. In the real world, there is always some loss associated with these conversions (typically these are above 90 percent efficient), dissipated as heat. Switch-mode power supplies also typically waste less energy than a linear regulator.

Why use higher voltages?

There are two main reasons to use higher voltages. First, switch-mode power supplies are more efficient than linear regulators which decrease voltages via heat dissipation. This is especially important for keeping our phones and their batteries cool.

The second relates to power loss over USB cables, particularly longer ones. A resistor, such as a length of wire, drops a voltage based on the current passing through it (Ohm’s law V=IR). Transmitting the same power using a higher voltage and lower current loses less of power over the length of the cable. This is more efficient and why the main power grid is hundreds of volts and not 5V.

However, the trade-off is that buck converters are more readily current-limited than linear regulators. The maximum output power depends on the inductor size, capacitor and voltage ripple, as well as the switching frequency, in addition to the power capabilities of the transistors. It’s only possible to reach very high currents via a more traditional linear voltage regulator. This is why some of the low voltage 5V fast charging technologies, like those from Huawei and OPPO, offer more total power than higher voltage buck-switching versions from Qualcomm and Samsung.

MediaTek Pump Express Bypass diagram

MediaTek MediaTek’s latest Pump Express technology caters to both switch mode and linear regulator charging.

The diagram above shows how MediaTek’s PumpExpress 3.0 and 4.0 manage to reach up to 5A of charging current. If a 5A cable is connected, its technology bypasses the conventional switching charger to enable a higher current. In this case, the circuit negotiates the required voltage over the data lines, raising and lowering the Vbus charging voltage for maximum efficiency.

Dash Charge

Wrap up

Fast charging encompasses a range of different possible technologies, each with their own pros and cons. This is partly why there are so many different standards on the market, as companies take their own approaches to speed up charging and maximize battery longevity.

A few generations ago, high voltage charging was becoming the norm and now technologies are implementing lower controlled voltages and high currents to boost speeds even further. However, this necessitates thicker cables and adds another compatibility headache.

USB Power Delivery is already pretty widely adopted. It will likely form the backbone of all USB charging standards going forward, though we will likely see companies experiment with their own even faster solutions on top of supporting this universal standard.

Next: Charging habits to maximize battery life

Source: Android Zone

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How to Add One-Click Login With Google in WordPress

Do you want to add one-click login with Google to your WordPress site? Allowing users to login with their Gmail account saves them time because they wouldn’t have to remember their WordPress username and password. In this article, we will share how to easily add one-click Google login in WordPress.

How to add one-click login with Google in WordPress

Why You Should Add One-Click Google Login in WordPress?

Most internet users remain logged in to their Google accounts. This allows them to quickly access all Google apps like Gmail, Drive, Docs, Photos, and more without signing in separately for each app.

Having one-click Google login activated on your WordPress login page allows your users to quickly sign-in to your website using their Gmail account. It saves them time, and they wouldn’t have to enter their login credentials each time.

If your organization uses GSuite for professional business email addresses, then your team members can use your organization’s Google apps accounts for login.

If you run a simple WordPress blog, then you might not find this feature useful. However single sign-on feature like one-click Google login is very helpful for any websites that require users to login such as multi-author websites, membership websites, and websites selling online courses.

That being said, let’s take a look on how to easily add one-click login with Google to your WordPress website.

Adding One-Click Gmail Login in WordPress

First thing you need to do is install and activate the Google Apps Login plugin. For more details, see our step by step guide on how to install a WordPress plugin.

Upon activation, you need to go to Settings » Google Apps Login page in your WordPress admin area. Under the Main Setup tab, you’ll need to add Client ID and Client Secret code.

Apps login settings page

To get these details, you need to visit Google Developers Console. If you are not already logged in, then you will be asked to login with your Google account.

Next, you need to click on Start a project from the top menu. It will open a popup where you would click on New Project button to continue.

New project

Now, you need to add a project name and select the location. Project name can be anything, and Location will be your organization’s domain name (example.com). If you are logged in with your company’s Google account or your GSuite account, then it will add the location and organization automatically.

Project, location, and organization name

However, if you are creating a project from your personal Google account, then you can leave the location with No Organization selected.

Project name and location

Next, click on the Create button to continue.

You’ll now be redirected to APIs & Services dashboard. On this page, you need to click on Credentials from the left menu and go to OAuth consent screen page.

In the Email Address field, you need to add your email address that you have used to create this project. Also you need to add your website URL in the Homepage URL field and click on the Save button.

OAuth consent screen

After that, it will take you to the Credentials page again. Go ahead and click on the Create Credentials button to select OAuth client ID option.

OAuth client ID

Next, you need to select Web application as an Application type. In the Authorised JavaScript origins field, you need to enter your website URL (http://www.example.com), and add WordPress login page URL (http://www.example.com/wp-login.php) in the Authorised redirect URLs field.

Web application type

After that click on the Create button, and you’ll see your Client ID and Client Secret information in a popup.

Client ID and Client secret

You need to copy and paste these keys on the plugin’s settings page in your WordPress admin area.

Add client ID and client secret in WordPress

After that, you can simply logout from your WordPress admin account, and you’ll see a Login with Google button on your login screen.

Login with Google

Clicking on the button allows you to login with one-click into your WordPress account. However, keep in mind that users can only login with the Google account address that they have used on your website.

We hope this article helped you learn how to add one-click login with Google in WordPress. You may also want to see our guide on how to create a login popup modal in WordPress, and how to create a custom user registration form in WordPress.

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Source: Wordpres

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