Technological frontiers and embeddings: A visualization approach

Scott W. Cunningham, Jan H. Kwakkel

Research output: Chapter in Book/Report/Conference proceedingConference contribution book

2 Citations (Scopus)

Abstract

The paper concerns the measurement and forecasting of technological change, a topic relevant to many high-tech organizations and their customers. We revisit recent and classic data sets from technology forecasting data envelopment analysis (TFDEA) research and technometrics in light of a new visualization technique known as t-Distributed Stochastic Neighbor Embedding (t-SNE). The technique is a non-linear visualization technique for preserving local structure in high-dimensional spaces of data. The technique may be classified as a form of topological data analysis. Specifically each point in the space represents a potential technological design or implementation, and each line segment in the space represents a local measure of technological improvement or degradation. We hypothesize six distinct kinds of performance development in technology within this space including the frontier, the fold, the salient, the soliton, and the lock-in. Then we examine the spaces to determine which kinds of development are the best explanations for observed development. The technique is not extrapolative, and therefore cannot supplant existing technometric methods. Nonetheless the approach offers a useful diagnostic to existing technometric methods, and may help advance theories of technological development.
Original languageEnglish
Title of host publicationProceedings of PICMET '14 Conference
Subtitle of host publicationPortland International Center for Management of Engineering and Technology; Infrastructure and Service Integration
PublisherIEEE
Pages27-31
Publication statusPublished - 13 Oct 2014

Fingerprint

Visualization
Data envelopment analysis
Solitons
Degradation

Keywords

  • technological change
  • visualization approach
  • data analysis

Cite this

Cunningham, S. W., & Kwakkel, J. H. (2014). Technological frontiers and embeddings: A visualization approach. In Proceedings of PICMET '14 Conference: Portland International Center for Management of Engineering and Technology; Infrastructure and Service Integration (pp. 27-31). IEEE.
Cunningham, Scott W. ; Kwakkel, Jan H. / Technological frontiers and embeddings : A visualization approach. Proceedings of PICMET '14 Conference: Portland International Center for Management of Engineering and Technology; Infrastructure and Service Integration. IEEE, 2014. pp. 27-31
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Cunningham, SW & Kwakkel, JH 2014, Technological frontiers and embeddings: A visualization approach. in Proceedings of PICMET '14 Conference: Portland International Center for Management of Engineering and Technology; Infrastructure and Service Integration. IEEE, pp. 27-31.

Technological frontiers and embeddings : A visualization approach. / Cunningham, Scott W.; Kwakkel, Jan H.

Proceedings of PICMET '14 Conference: Portland International Center for Management of Engineering and Technology; Infrastructure and Service Integration. IEEE, 2014. p. 27-31.

Research output: Chapter in Book/Report/Conference proceedingConference contribution book

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AB - The paper concerns the measurement and forecasting of technological change, a topic relevant to many high-tech organizations and their customers. We revisit recent and classic data sets from technology forecasting data envelopment analysis (TFDEA) research and technometrics in light of a new visualization technique known as t-Distributed Stochastic Neighbor Embedding (t-SNE). The technique is a non-linear visualization technique for preserving local structure in high-dimensional spaces of data. The technique may be classified as a form of topological data analysis. Specifically each point in the space represents a potential technological design or implementation, and each line segment in the space represents a local measure of technological improvement or degradation. We hypothesize six distinct kinds of performance development in technology within this space including the frontier, the fold, the salient, the soliton, and the lock-in. Then we examine the spaces to determine which kinds of development are the best explanations for observed development. The technique is not extrapolative, and therefore cannot supplant existing technometric methods. Nonetheless the approach offers a useful diagnostic to existing technometric methods, and may help advance theories of technological development.

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Cunningham SW, Kwakkel JH. Technological frontiers and embeddings: A visualization approach. In Proceedings of PICMET '14 Conference: Portland International Center for Management of Engineering and Technology; Infrastructure and Service Integration. IEEE. 2014. p. 27-31