Data on ratepayers’ real-time energy use and real-time energy prices could, theoretically, drive a highly efficient and responsive energy consumption landscape.Under those conditions, people would constantly adjust their energy use, cut back when regional demand and prices are high and do energy-intensive tasks when overall demand and prices are low.

But in reality, during their busy lives people are unlikely to constantly check an energy portal website or notifications on their phone and adjust their thermostats or operate appliances in response.

That’s where many see an important role for third-party actors who essentially manage ratepayers’ energy use for them — adjusting their thermostats and other smart appliances in real time and otherwise helping people make changes that will reduce their usage during peak demand times.

But to do this, third-party companies need access to customers’ energy use data in real-time. Only recently have utilities been able to provide customers with detailed data on their own energy use, thanks to smart meters and other smart grid-related technology. But utilities typically do not provide this data to third parties, in part because of privacy and security concerns.

In addition to managing devices and appliances, the U.S. Department of Energy says sharing energy-use data with third parties could help with sizing and financing rooftop solar panels and help contractors more easily verify home energy savings. Large users can already sell their demand response into energy marketplaces, but residential users would typically be too small to participate. Third parties could aggregate the demand response (strategic energy use reduction) of numerous residents and sell it into the marketplace, then channel the financial benefits — minus their own cut — back to residents.

Wind, natural gas, and solar made up almost all new electric generation capacity in 2015, accounting for 41%, 30%, and 26% of total additions, respectively, according to preliminary data. The data also show a record amount of distributed solar photovoltaic (PV) capacity was added on rooftops throughout the country in 2015. The trend of wind, natural gas, and solar additions making up most new capacity is likely to continue in 2016.

Wind. Wind installations steadily increased in 2014 and 2015 from less than 1,000 megawatts (MW) added in 2013. Uncertainty surrounding the extensions and modifications of the federal production tax credit (PTC) over the past several years led to large fluctuations in annual wind additions. The record amount of additions in 2012 was followed by a precipitous drop-off in 2013 and a subsequent rebound in 2014 and 2015—a pattern also visible with previous years' PTC expiration and renewal cycles. Texas added the most wind capacity (42% of total wind additions), followed by Oklahoma, Kansas, Iowa, and North Dakota.

Natural gas. Natural gas additions, mainly combined-cycle plants, were lower in 2015 than in recent years. New Jersey and Texas together made up half of all natural gas additions.
In New Jersey, most of the new capacity came from two combined-cycle plants, the Newark Energy Center (685 MW) and the Woodbridge Energy Center (795 MW). 

Distributed solar PV. Distributed PV saw significant growth in 2015, particularly in the residential sector, where total installed capacity rose much faster over the year than in the industrial or commercial sectors. While still far behind top distributed solar PV states, several states saw notable growth in 2015.