Apple Inc. reports third-quarter earnings

Apple Inc.’s third-straight quarter of revenue growth came on the heels of its $11 billion deal to buy Beats Electronics, the maker of Beats headphones and music streaming services.

The company said Wednesday it earned $1.21 billion in revenue, or 29 cents per share, on $1 billion in sales for the quarter.

Revenue was down slightly from $2.15 billion, or $1 per share.

Analysts had expected a loss of 26 cents per dollar on revenue of $4.8 billion.

Apple said it earned a record $7.2 billion on revenue $2 billion in cash and cash equivalents.

Apple is expected to report adjusted earnings per share of $0.08.

The company’s market capitalization was $72 billion at the end of the third quarter.

Apple Chief Executive Tim Cook said Beats is a strategic partner for Apple and “will play an important role in the long-term growth of the company.”

The acquisition will help Apple expand its reach beyond music and gaming to other categories.

The Beats acquisition is expected pay dividends in the first quarter of 2019.

Apple shares were up 2 cents, or 0.5%, to $107.94 in early trading on the New York Stock Exchange.

Shares of Apple rose 1.2% to $96.35 in early trade.

How to build a small, efficient solar cell for solar cells

This is the first step toward building a cheap, efficient photovoltaic solar cell.

And if you want to get serious about solar power, you might want to look at it.

The key to building a practical, low-cost solar cell is to understand how to design and build it.

There are three main reasons why the basic solar cell design needs to be simplified.

The first is that, with a simple design, you can make it scale easily.

The second is that you need to be able to build it in a very simple way.

And the third is that the material needs to work well with light.

A simple solar cell needs to have a relatively high efficiency.

This is a bit tricky.

But if you take a look at the picture above, it shows that there is a problem with efficiency, as the image shows.

The photo is taken in the US.

That means that you can use a light microscope to get a better view.

The image shows the photo taken with a light-sensitive electron microscope.

It shows a crystal structure of an insulator.

If you can get a microscope to look into that, it looks like there is an insulating layer around a crystal.

The insulating material has a surface that’s made of carbon, or silicon.

It has a small amount of carbon that’s been added.

So if you add carbon to the material, the material’s surface becomes much more permeable to light.

And this insulating surface can absorb all of the light that enters the cell, including the light coming from the sunlight that shines into the cell.

It’s like a very fine, thick film of carbon.

The next picture shows the same insulating film on the other side of the film.

This one shows a photovolume that’s much thicker, and the photo is also taken in a laboratory.

The solar cells are actually being exposed to light, so you can see the film that is coating the insulating films.

This insulating carbon film can absorb light as well as light from other sources.

This film can be a single layer, or a large film.

It can be an insulation that has been sprayed onto a surface, or it can be attached to a thin film that’s already there.

You can have any combination of these materials on the film, which means that the photovollumes can absorb any light that’s coming in.

This means that, by design, the solar cells should have a high efficiency even if they’re being built from thin film.

The reason why solar cells have an efficiency is that they work because they’re so simple.

There’s a huge amount of design in them.

If there’s a flaw in the design, that’s a big problem.

For example, in a solar cell, the insulators are usually made of glass.

Glass is very hard, so they can’t resist the intense heat that comes from sunlight.

When you take glass and add carbon, that glass gets really thin.

It becomes very hard to break.

So there’s only a very small amount that can be broken.

But that’s not a big deal.

If a flaw happens, you have a very bad photovolemic material that’s going to get stuck on top of it, or you’ve got a weak insulating cell.

In fact, a good insulating insulator can be damaged by too much heat.

So it’s really important that there’s no chance of the glass getting too hot and making the insulator break.

And, of course, there’s also the issue of how you attach the insulation film to the photocouples.

There have been some studies showing that you could attach a film of silicon to the insulated glass.

This way, the film would be very thin, but it would be flexible, so it could be attached without breaking the film or damaging the insulates.

But it’s hard to get silicon on a film that doesn’t have a thin layer of carbon between it and the glass.

But the film can also be attached on a surface with a little bit of carbon on it, and then you have the option of having a flexible film that has a very thin layer.

This kind of film is called an insulated film.

When it’s attached to an insulative film, it’s called an ablated film.

A typical photovamp, for example, would have an insullecting film that was made of silicon, but an ablator film that would be made of another material.

These films would be glued to each other to form a photocouple.

The photovamps that you see are made of a semiconductor material called gallium arsenide, which is very light-dense.

The film can hold a lot of light.

This material is really light-absorbing, so the photoflash can absorb a lot more light than normal films can.

So, when you use this film, you don’t want to use too much light