Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by Crossref.
Thompson, Clarissa A.
Morris, Bradley J.
and
Sidney, Pooja G.
2017.
Are Books Like Number Lines? Children Spontaneously Encode Spatial-Numeric Relationships in a Novel Spatial Estimation Task.
Frontiers in Psychology,
Vol. 8,
Issue. ,
Chesney, Dana L.
and
Matthews, Percival G.
2018.
Task Constraints Affect Mapping From Approximate Number System Estimates to Symbolic Numbers.
Frontiers in Psychology,
Vol. 9,
Issue. ,
Sidney, Pooja G.
Thompson, Clarissa A.
and
Opfer, John E.
2019.
The Cambridge Handbook of Cognition and Education.
p.
148.
Meng, Rui
Matthews, Percival G.
and
Toomarian, Elizabeth Y.
2019.
The Relational SNARC: Spatial Representation of Nonsymbolic Ratios.
Cognitive Science,
Vol. 43,
Issue. 8,
Sidney, Pooja G.
and
Thompson, Clarissa A.
2019.
Implicit Analogies in Learning: Supporting Transfer by Warming Up.
Current Directions in Psychological Science,
Vol. 28,
Issue. 6,
p.
619.
Matthews, Percival G.
and
Ziols, Ryan
2019.
Constructing Number.
p.
213.
Kalra, Priya B.
Hubbard, Edward M.
and
Matthews, Percival G.
2020.
Taking the relational structure of fractions seriously: Relational reasoning predicts fraction knowledge in elementary school children.
Contemporary Educational Psychology,
Vol. 62,
Issue. ,
p.
101896.
Marinova, Mila
and
Reynvoet, Bert
2020.
Can you trust your number sense: Distinct processing of numbers and quantities in elementary school children.
Journal of Numerical Cognition,
Vol. 6,
Issue. 3,
p.
304.
Park, Yunji
and
Matthews, Percival G.
2021.
Revisiting and refining relations between nonsymbolic ratio processing and symbolic math achievement.
Journal of Numerical Cognition,
Vol. 7,
Issue. 3,
p.
328.
Park, Yunji
Viegut, Alexandria A.
and
Matthews, Percival G.
2021.
More than the sum of its parts: Exploring the development of ratio magnitude versus simple magnitude perception.
Developmental Science,
Vol. 24,
Issue. 3,
Mielicki, Marta K.
Fitzsimmons, Charlies J.
Woodbury, Lauren H.
Marshal, Hannah
Zhang, Dake
Rivera, Ferdinand D.
and
Thompson, Clarissa A.
2021.
Effects of figural and numerical presentation formats on growing pattern performance.
Journal of Numerical Cognition,
Vol. 7,
Issue. 2,
p.
125.
Mielicki, Marta K.
Schiller, Lauren K.
Fitzsimmons, Charles J.
Scheibe, Daniel
and
Thompson, Clarissa A.
2022.
Perceptions of ease and difficulty, but not growth mindset, relate to specific math attitudes.
British Journal of Educational Psychology,
Vol. 92,
Issue. 2,
p.
707.
Chesney, Dana L.
and
Matthews, Percival G.
2022.
Circling around number: People can accurately extract numeric values from circle area ratios.
Psychonomic Bulletin & Review,
Vol. 29,
Issue. 4,
p.
1503.
Sidney, Pooja G.
and
Shirah, Julie F.
2023.
Surface-to-structure shifts in rational number categories.
Cognitive Development,
Vol. 68,
Issue. ,
p.
101386.
Thompson, Clarissa A.
Mielicki, Marta K.
Rivera, Ferdinand
Fitzsimmons, Charles J.
Scheibe, Daniel A.
Sidney, Pooja G.
Schiller, Lauren K.
Taber, Jennifer M.
and
Waters, Erika A.
2023.
Leveraging Math Cognition to Combat Health Innumeracy.
Perspectives on Psychological Science,
Vol. 18,
Issue. 1,
p.
152.
Target article
From “sense of number” to “sense of magnitude”: The role of continuous magnitudes in numerical cognition
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