Ghana’s cocoa production belt also serves as the main forests repository of the country. Cocoa farm- ing is both a direct and indirect driver of deforesta- tion in Ghana (UNEP, 2008). This implies that critical interventions are needed to deal with deforestation emanating from cocoa production.
This report presents and reflects on the opportunities that new technological developments related to automation and precision agriculture (e.g. robotics) can offer to agriculture in developing countries. These technologies are mainly targeted to support farmers that struggle with the cost of labour when harvesting crops and to tackle the declining availability of manpower for general cropping operations.
Le présent rapport étudie les possibilités que les nouvelles avancées technologiques liées à l’automatisation et à l’agriculture de précision (la robotique, par exemple) peuvent offrir à l’agriculture dans les pays en développement. Ces technologies visent principalement à aider les agriculteurs appelés à faire face au coût de la main-d’oeuvre nécessaire pour les opérations de récolte, ainsi qu’à répondre au problème de la raréfaction de la main-d’oeuvre disponible pour l’ensemble des travaux agricoles.
Agricultural research continues to be a good investment. The studies show that investments in international and national agricultural research account for almost all of the total factor productivity (TFP) growth in SSA and large shares of agricultural growth globally. The existing agricultural research institutions have, on average, delivered rates of return to public investment above 30-40%, which is much higher than the 5-10% available to other public investments or the 2-5% cost of borrowing public funds.
In the last decade, solar energy has experienced a rapid growth, which brings both environmental and economic benefits. In many countries, there is still no electricity grid extension in rural areas, and in the absence of a reliable electricity supply, farmers have to resort to diesel-based pumping irrigation systems. The solar photovoltaic (PV) system generates clean energy and eliminates the risk of environmental pollution in the form of oil spills, contaminated soil and carbon dioxide emissions.
Agrifood systems are undergoing a transformation with the aim to provide safer, more affordable, and healthier diets for all, produced in a sustainable manner while delivering just and equitable livelihoods: a key to achieving the UN’s 2030 Agenda for Sustainable Development. However, this transformation needs to be executed in the global context of major challenges facing the food and agriculture sectors, with drivers such as climate change, population growth, urbanization, and natural resources depletion compounding these challenges.
Since 2017, in line with COAG’s recommendation, the Research and Extension Unit engaged in the development of a participatory AIS assessment framework including a customizable toolbox for countries with a totally new capacity development perspective. The assessment framework is meant for actors of the national agricultural innovation systems, i.e.
The United States Agency for International Development (USAID) funded the Assets and Market Access Innovation Lab (AMA IL) to advance knowledge and understanding of development approaches and technologies in order to increase rural households’ ability to acquire, protect, and effectively utilize productive assets. This evaluation assessed AMA IL’s overall program performance across five themes: research quality; outreach and dissemination; policy; capacity building; program management; and future directions.
This evaluation seeks to understand the impact which certain measures of the CAP have had on reducing GHG emissions, agriculture’s vulnerability to climate change and its ability to provide adaptation and mitigation services to society. Most of the CAP measures analysed do not have climate action as their intended purpose but may have it as a secondary purpose. Some, such as those which sustain certain forms of agricultural production responsible for emissions, exist for economic, social and sometimes other environmental reasons.
A conceptual framework that promotes an integrated and comprehensive approach to Capacity Development for Agricultural Innovation Systems (CD4AIS Framework) was developed in Year 1 of the project. It argues that for innovations to emerge, functional capacities are needed. There are 4 functional capacities i.e. capacity to navigate complexity, to collaborate, reflect and learn and engage in strategic and political process. These capacities should be inherent within individuals, organisations, systems level (local and national level including policy systems).