Certification Systems as Tools for Natural Asset Building: Potential, Experiences to Date, and Critical Challenges

Certification systems are becoming important tools to encourage and reward social and environmental responsibility. This paper explores whether these systems, which generally have not been designed for the explicit aim of poverty reduction, can assist poor people, either individually or in community-based and small-to-medium production units, to build their natural assets as a basis for sustainable livelihoods. The paper examines two leading certification systems -- the Forest Stewardship Council(TM); and the Fair Trade Certified(TM); system -- and emerging systems in tourism and mining. The results to date have been mixed. In the forestry sector, poverty reduction benefits of certification have been modest relative to its environmental benefits. In the agricultural commodity trade, where certification systems have been designed with a stronger focus on reducing poverty, the benefits have been greater. The long-term challenge is to ensure that the rapid global uptake and 'mainstreaming' of certification systems does not create new hurdles for low-income individuals and communities

Can Advocacy-Led Certification Systems Transform Global Corporate Practices? Evidence, and Some Theory

There is emerging evidence that globalization is beginning to provide new opportunities for global coalitions of advocacy groups to bring market-based pressures to bear upon major transnational firms in a way that promotes higher standards of social and environmental responsibility in production processes and trade relations. This can be seen as successful citizen-led attention to the “production and process methods” which the Uruguay Round of trade negotiations explicitly chose to omit. More broadly it may reflect the increased importance of global branding, improved awareness in both consumer and financial markets of the social and environmental practices of firms, and collaboration on the part of producers to reduce their risk of brand-damaging attacks on the social and environmental responsibility of their practices. The emergence and growth of the Forest Stewardship Council as the “gold standard” for sustainable forest management, and the expensive attempts by the forest products industry to create industry-driven substitute standards, may be the pivotal example of this phenomenon. The further growth of certified Fair Trade practices under Transfair USA is another example. Both cases provide important lessons as to the elements of present and future success for this movement. They may also represent creative new solutions for problems of persistent poverty by using the leverage of markets in the global North to improve the ability of workers, farmers, and other producers in the global South to build natural assets in ways that generate socially and environmentally sustainable livelihoods.

Certification Systems as Tools for Natural Asset Building: Potential, Experiences to Date, and Critical Challenges

Certification systems are becoming important tools to encourage and reward social and environmental responsibility. This paper explores whether these systems, which generally have not been designed for the explicit aim of poverty reduction, can assist poor people, either individually or in community-based and small-to-medium production units, to build their natural assets as a basis for sustainable livelihoods. The paper examines two leading certification systems – the Forest Stewardship Council™ and the Fair Trade Certified™ system – and emerging systems in tourism and mining. The results to date have been mixed. In the forestry sector, poverty reduction benefits of certification have been modest relative to its environmental benefits. In the agricultural commodity trade, where certification systems have been designed with a stronger focus on reducing poverty, the benefits have been greater. The long-term challenge is to ensure that the rapid global uptake and ‘mainstreaming’ of certification systems does not create new hurdles for low-income individuals and communities.certification, social responsibility, environmental responsibility, povery reduction, natural assets, sustainable livelihoods, Forest Stewardship Council™, Fair Trade Certified™, tourism, mining, forestry, agriculture, globalization

Shape and deformation measurement using heterodyne range imaging technology

Range imaging is emerging as a promising alternative technology for applications that require non-contact visual inspection of object deformation and shape. Previously, we presented a solid-state full-field heterodyne range imaging device capable of capturing three-dimensional images with sub-millimetre range resolution. Using a heterodyne indirect time-of-flight configuration, this system simultaneously measures distance (and intensity), for each pixel in a cameras field of view. In this paper we briefly describe our range imaging system, and its principle of operation. By performing measurements on several metal objects, we demonstrate the potential capabilities of this technology for surface profiling and deformation measurement. In addition to verifying system performance, the reported examples highlight some important system limitations. With these in mind we subsequently discuss the further developments required to enable the use of this device as a robust and practical tool in non-destructive testing and measurement applications

A power-saving modulation technique for time-of-flight range imaging sensors

Time-of-flight range imaging cameras measure distance and intensity simultaneously for every pixel in an image. With the continued advancement of the technology, a wide variety of new depth sensing applications are emerging; however a number of these potential applications have stringent electrical power constraints that are difficult to meet with the current state-of-the-art systems. Sensor gain modulation contributes a significant proportion of the total image sensor power consumption, and as higher spatial resolution range image sensors operating at higher modulation frequencies (to achieve better measurement precision) are developed, this proportion is likely to increase. The authors have developed a new sensor modulation technique using resonant circuit concepts that is more power efficient than the standard mode of operation. With a proof of principle system, a 93–96% reduction in modulation drive power was demonstrated across a range of modulation frequencies from 1–11 MHz. Finally, an evaluation of the range imaging performance revealed an improvement in measurement linearity in the resonant configuration due primarily to the more sinusoidal shape of the resonant electrical waveforms, while the average precision values were comparable between the standard and resonant operating modes

Range imager performance comparison in homodyne and heterodyne operating modes

Range imaging cameras measure depth simultaneously for every pixel in a given field of view. In most implementations the basic operating principles are the same. A scene is illuminated with an intensity modulated light source and the reflected signal is sampled using a gain-modulated imager. Previously we presented a unique heterodyne range imaging system that employed a bulky and power hungry image intensifier as the high speed gain-modulation mechanism. In this paper we present a new range imager using an internally modulated image sensor that is designed to operate in heterodyne mode, but can also operate in homodyne mode. We discuss homodyne and heterodyne range imaging, and the merits of the various types of hardware used to implement these systems. Following this we describe in detail the hardware and firmware components of our new ranger. We experimentally compare the two operating modes and demonstrate that heterodyne operation is less sensitive to some of the limitations suffered in homodyne mode, resulting in better linearity and ranging precision characteristics. We conclude by showing various qualitative examples that demonstrate the system’s three-dimensional measurement performance

Heterodyne range imaging as an alternative to photogrammetry

Solid-state full-field range imaging technology, capable of determining the distance to objects in a scene simultaneously for every pixel in an image, has recently achieved sub-millimeter distance measurement precision. With this level of precision, it is becoming practical to use this technology for high precision three-dimensional metrology applications. Compared to photogrammetry, range imaging has the advantages of requiring only one viewing angle, a relatively short measurement time, and simplistic fast data processing. In this paper we fist review the range imaging technology, then describe an experiment comparing both photogrammetric and range imaging measurements of a calibration block with attached retro-reflective targets. The results show that the range imaging approach exhibits errors of approximately 0.5 mm in-plane and almost 5 mm out-of-plane; however, these errors appear to be mostly systematic. We then proceed to examine the physical nature and characteristics of the image ranging technology and discuss the possible causes of these systematic errors. Also discussed is the potential for further system characterization and calibration to compensate for the range determination and other errors, which could possibly lead to three-dimensional measurement precision approaching that of photogrammetry

The Waikato range imager

We are developing a high precision simultaneous full-field acquisition range imager. This device measures range with sub millimetre precision in range simultaneously over a full-field view of the scene. Laser diodes are used to illuminate the scene with amplitude modulation with a frequency of 10MHz up to 100 MHz. The received light is interrupted by a high speed shutter operating in a heterodyne configuration thus producing a low-frequency signal which is sampled with a digital camera. By detecting the phase of the signal at each pixel the range to the scene is determined. We show 3D reconstructions of some viewed objects to demonstrate the capabilities of the ranger

Collaboration: It Is Much More Than the Technology

A joint study conducted with the University of Central Florida and the National Aeronautics and Space Agency's (NASA) Kennedy Space Center (KSC) resulted in a new approach to the collaboration issues that had troubled the Agency. We believe in teams. We believe in the concept of collaboration. We never doubted Douglas Engelbart's thesis-- "Our very survival depends on our ability to work together, more effectively, to get collectively smarter. Computers -- when used properly -- can help us do that". It was not lack of trying. Predictably, NASA engineers had worked as if better and better technology would resolve the matter. It had not. The study itself provided an insight, an "aha! moment that pointed us toward the problems of collaboration we had to solve. People quickly saw that we had to remove barriers and make it easier to share data, coordinate efficiently, work together to add value and create corporate memory. This paper describes what happened