Dendrochronology of U.S. immigration

Cruz, Pedro; Wihbey, John; Ghael, Avni; Shibuya, Felipe; Costa, Stephen

doi:10.1075/idj.25.1.01cru

Article published In: Information Visualization
Edited by Marian Dörk and Isabel Meirelles
[Information Design Journal 25:1] 2019
► pp. 6–20

Get fulltext from our e-platform

Download PDF

Dendrochronology of U.S. immigration

Pedro Cruz | Northeastern University

John Wihbey | Northeastern University

Avni Ghael | Northeastern University

Felipe Shibuya | State University of New York at Buffalo

Stephen Costa | Boston Planning & Development Agency

Available under the Creative Commons Attribution-NonCommercial (CC BY-NC) 4.0 license.

For any use beyond this license, please contact the publisher at rights@benjamins.nl.

Published online: 16 March 2020

https://doi.org/10.1075/idj.25.1.01cru

Abstract

Immigrants are central to the identity of the United States, the population of which has grown in number and diversity as a function of new arrivals from around the globe. This article describes a visualization project that uses the visual metaphor of tree rings to explore the contribution of immigrants to the country’s population. Immigrants and native-born persons are represented and differentiated as cells in trees, with layered annual rings capturing patterns of population growth. These rings register, in their shape and color, certain environmental conditions. In order to mimic the natural process by which growth rings are formed, we devised a computational system that simulates the growth of trees as if cells were data-units. Dendrochronology involves dating certain events by analyzing patterns of growth in trees. Analogously, in our visualizations the rings can be counted and dated, showing the chronological evolution of the population. The dendrochronology theme is a poetic take on the data, yet it is also a functional and conceptual space that is used to construct language and rationales on that data. The tree-growth process not only inspires the appearance of the visualizations but also informs the rules of the computational system that creates them.

Keywords: information visualization, data visualization, information design, data art, graphic design, figurative metaphors

Article outline

1.Introduction
2.Related approaches
3.Tree rings for immigration
4.Data
5.Rules and implementation
6.Results
7.Synthesis
References

References (14)

References

Cruz, P. (2015). Wrongfully right: applications of semantic figurative metaphors in information visualization (pp. 14–21). Presented at the IEEE VIS Arts Program Annotated Projects , Chicago.

Cruz, P., & Machado, P. (2016). Pulsing Blood Vessels: A Figurative Approach to Traffic Visualization. IEEE Computer Graphics and Applications, 36(2), 16–21.

Cruz, P., Wihbey, J., Ghael, A., Costa, S., & Shibuya, F. (2018). Process of simulating tree rings for immigration in the U.S. (pp. 1–17). Presented at the IEEE VIS Arts Program Annotated Projects , Berlin.

Donaldson, L. A., & Singh, A. P. (2016). Reaction Wood. In Y. S. Kim, R. Funada, & A. P. Singh (Eds.), Secondary Xylem Biology (pp. 93–110). Boston: Academic Press.

D’Efilippo, V., & Ball, J. (2016). A rough guide to conflict. In The Infographic History of the World. Firefly Books.

Dorling, D. (1996). Area cartograms: their use and creation. Concepts and Techniques in Modern Geography, 591.

Fahn, A., Burley, J., Longman, K. A., & Mariaux, A. (1981). Possible contributions of wood anatomy to the determination of the age of tropical trees. In F. H. Bormann & G. Berlyn (Eds.), Age and growth rate of tropical trees: new directions for research (pp. 31–54). New Haven: Yale University.

Fruchterman, T. M. J., & Reingold, E. M. (1991). Graph Drawing by Force-directed Placement. Software: Practice and Experience, 21(11), 1129–1164.

Hinrichs, U., Schmidt, H., & Carpendale, S. (2008). EMDialog: Bringing Information Visualization into the Museum. IEEE Transactions on Visualization and Computer Graphics, 14(6), 1181–1188.

Kim, Y. S., Funada, R., & Adya, P. S. (2016). Secondary Xylem Biology. Academic Press.

Manovich, L. (2011). What is visualisation? Visual Studies, 26(1), 36–49.

Ruggles, S., Flood, S., Goeken, R., Grover, J., Meyer, E., Pacas, J., & Sobek, M. (2018). IPUMS USA: Version 8.0. Minneapolis.

Vande Moere, A., & Lau, A. (2007). In-Formation Flocking: An Approach to Data Visualization Using Multi-agent Formation Behavior. Acal, 48281(Chapter 26), 292–304.

Wihbey, J. P., Jackson, S. J., Cruz, P. M., Welles, B. F. (2020). Visualizing diversity: Data deficiencies and semiotic strategies. In H. Kennedy & M. Engebretsen (Eds.), Data Visualization in Society. Amsterdam: Amsterdam University Press.

Cited by (4)

Cited by four other publications

Order by:

Liu, Guanhong, Yutong Jiang, Xiaoke Yan, Nan Cao & Yang Shi

2025. Proceedings of the Extended Abstracts of the CHI Conference on Human Factors in Computing Systems, ► pp. 1 ff.

Dasu, Keshav, Yun-Hsin Kuo & Kwan-liu Ma

2023. Character-Oriented Design for Visual Data Storytelling. IEEE Transactions on Visualization and Computer Graphics ► pp. 1 ff.

Brehmer, Matthew, Robert Kosara & Carmen Hull

2022. Generative Design Inspiration for Glyphs with Diatoms. IEEE Transactions on Visualization and Computer Graphics 28:1 ► pp. 389 ff.

Ploehn, Cathryn, Molly Steenson & Daragh Byrne

2020. 2020 IEEE VIS Arts Program (VISAP), ► pp. 9 ff.

This list is based on CrossRef data as of 11 december 2025. Please note that it may not be complete. Sources presented here have been supplied by the respective publishers. Any errors therein should be reported to them.