SBIR-STTR Award

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is a healthier honeybee population to increase food security. According to the Food and Agriculture Organization, annual production must increase by 60% from 2007 to produce enough food for an estimated 9.1 billion people by 2050, which will be impossible without honeybee pollination (Food and Agriculture Organization, 2012). Honeybee populations have declined precipitously for the past 60 years?a total loss of 3 million hives (National Agricultural Statistics Service, 2007). Annual hive losses cost the U.S. economy $2 billion (National Agricultural Statistics Service, 2016; The White House, 2014). This project aims to enhance scientific understanding of the problem by finding practical solutions to hive loss for beekeepers, advancing IoT applications in beekeeping, and automating data analysis for beekeepers. Researchers and experts suspect the declines are due to multiple factors, but research is limited by a lack of technology tracking the hives on a large scale. Researchers' inability to perform analysis on a large, diverse dataset has obstructed their ability to draw conclusions on causes of hive loss and drive innovation on traditional beekeeping methods. This proposed project will advance Internet of Things applications in beekeeping by automating data analysis for beekeepers through algorithm building. Several studies built models to describe actions inside the hive. However, these are built on limited data or are theoretical. Henry et al., 2016 mentioned the need for predictive algorithms to be expanded to larger data sets to reduce hive loss. Data driven beekeeping is in its infancy as an industry, but based on the success in the AgTech space, data monitoring will be a necessary step in solving colony health problems. The project will take a database of over 4,000 hives to improve research models for practical monitoring. This database will be paired with sensor and monitoring data from project hives. Through the project hives the company will confirm the sensor quality for commercialization. The company will create a baseline model of a healthy hive to detect anomalies. These anomalies will be worked into a predictive model to detect problems related to pests and diseases in the hive. The company will look for broad detection of a threatened hive, then drill down into specific problems (like Varroa mites). These finds will be included in monitoring products offered to beekeepers.

The broader impact of this Small Business Innovation Research (SBIR) Phase II project safeguards domestic food supply by improving honeybee health. Honeybees pollinate 1/3 of domestic food supply and contribute more than $15 billion to the U.S. economy. Although honeybee populations are at a 20-year high in the U.S., the cost to keep them alive is at its historical peak. This project reduces labor costs for commercial beekeepers, allowing them to devote more time to restoring hives that show signs of poor health and infestation. The product can be used to optimize hive placement, allowing growers to pollinate using the smallest number of hives. As growers' demand for hives decreases, the number of hives shipped across the country to pollinate crops will be reduced, resulting in a more robust stock of commercial honeybees.This proposed project expands on research developed in Phase I to grow the product from its first version into a scalable product, which includes predictive model improvements, additional data collection, mobile app development and additional field testing. A major component of the Phase II grant will be improving accuracy and performance of the hive strength model. Additional data collection will be important in Phase II to improve the model to perform well in a wider range of ambient conditions. By the end of Phase II, full automation of the software allows for the product to be used at all times. A major component of the Phase II work will be the development of a web-based mobile application that can take infrared pictures using smartphone camera attachments, upload images automatically to a database, and provide real time analytics on the images. This project is a breakthrough in the crop pollination space using infrared imagery that can be adapted to improve thermodynamic insights across many verticals.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.