D. Taylor, S. Tillery, and A. Schwartz, "Direct cortical control of 3d neuroprosthetic devices," Science, vol. 5574, no. 296, pp. 1829--32, Jun 2002. Home/Search Document Not in Database Summary Related Articles Check |
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Neural Decoding of Cursor Motion Using a Kalman Filter - Wu, Black, Gao.. (2003) (1 citation) (Correct)
....are more accurate than previously reported results and the model provides insights into the nature of the neural coding of movement. 1 Introduction Recent results have demonstrated the feasibility of direct neural control of devices such as computer cursors using implanted electrodes [5, 9, 11, 14]. These results are enabled by a variety of mathematical decoding methods that produce an estimate of the system state (e.g. hand position) from a sequence of measurements (e.g. the firing rates of a collection of cells) Here we argue that such a decoding method should (1) have a sound ....
....this movement from the firing rates of a population of cells. Simultaneous recordings are acquired from an array consisting of 100 microelectrodes [6] implanted in the arm area of primary motor cortex (MI) of a Macaque monkey; recordings from this area have been used previously to control devices [5, 9, 10, 11, 14]. The monkey views a computer monitor while gripping a two link manipulandum that controls the 2D motion of a cursor on the monitor (Figure 1a) We use the experimental paradigm of [9] in which a target dot appears in a random location on the monitor and the task requires moving a feedback dot ....
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Taylor. D., Tillery, S., Schwartz, A. (2002). Direct cortical control of 3D neuroprosthetic devices. Science, Jun. 7;296(5574):1829-32.
Neural Decoding of Cursor Motion Using a Kalman Filter - Wu, Black, Gao.. (2003) (1 citation) (Correct)
....are more accurate than previously reported results and the model provides insights into the nature of the neural coding of movement. 1 Introduction Recent results have demonstrated the feasibility of direct neural control of devices such as computer cursors using implanted electrodes [5, 9, 11, 14]. These results are enabled by a variety of mathematical decoding methods that produce an estimate of the system state (e.g. hand position) from a sequence of measurements (e.g. the firing rates of a collection of cells) Here we argue that such a decoding method should (1) have a sound ....
....this movement from the firing rates of a population of cells. Simultaneous recordings are acquired from an array consisting of ### microelectrodes [6] implanted in the arm area of primary motor cortex (MI) of a Macaque monkey; recordings from this area have been used previously to control devices [5, 9, 10, 11, 14]. The monkey views a computer monitor while gripping a two link manipulandum that controls the 2D motion of a cursor on the monitor (Figure 1a) We use the experimental paradigm of [9] in which a target dot appears in a random location on the monitor and the task requires moving a feedback dot ....
[Article contains additional citation context not shown here]
Taylor. D., Tillery, S., Schwartz, A. (2002). Direct cortical control of 3D neuroprosthetic devices. Science, Jun. 7;296(5574):1829-32.
Spatio-Spectral Filters for Improving the.. - Lemm, Blankertz.. (2005) (1 citation) (Correct)
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D. Taylor, S. Tillery, and A. Schwartz, "Direct cortical control of 3d neuroprosthetic devices," Science, vol. 5574, no. 296, pp. 1829--32, Jun 2002.
Automatic Spike Sorting for Neural Decoding - Wood Fellows Donoghue (2004) (Correct)
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D. Taylor, S. Tillery, and A. Schwartz, "Direct cortical control of 3D neuroprosthetic devices," Science, vol. 296, no. 5574, pp. 1829--1832, 2002.
On the Variability of Manual Spike Sorting - Frank Wood Michael (2004) (Correct)
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D. Taylor, S. Tillery, and A. Schwartz, "Direct cortical control of 3d neuroprosthetic devices," Science, vol. 296, no. 5574, pp. 1829--1832, 2002.
Modeling and Decoding Motor Cortical Activity.. - Wu, Black.. (2004) (Correct)
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D. Taylor, S. H.S. Helms Tillery, and A. Schwartz, "Direct cortical control of 3D neuroprosthetic devices," Science, vol. 296, no. 5574, pp. 1829--1832, 2002.
Bayesian Population Decoding of Motor Cortical.. - Gao, Bienenstock.. (2005) (Correct)
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Taylor, D., Helms Tillery, S., and Schwartz, A. (2002). Direct cortical control of 3D neuroprosthetic devices. Science, 296, 1829--1832.
Neural Decoding of Cursor Motion Using a Kalman Filter - Wu, Black, Gao.. (2003) (1 citation) (Correct)
No context found.
Taylor. D., Tillery, S., Schwartz, A. (2002). Direct cortical control of 3D neuroprosthetic devices. Science, Jun. 7;296(5574):1829-32.
Conductive Polymer "Molecular Wires" For - Neuro-Robotic Interfaces Alik (2004) (Correct)
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D. M. Taylor, S. I. Helms Tillery, and A. B. Schwartz, "Direct cortical control of 3D neuroprosthetic devices," Science, vol. 296, no. 5574, pp. 1829--32, 2002.
Modeling and Decoding Motor Cortical Activity.. - Wu, Black.. (2004) (Correct)
No context found.
D. Taylor, S. Helms Tillery, and A. Schwartz, "Direct cortical control of 3d neuroprosthetic devices," Science, vol. 296, no. 5574, pp. 1829--1832, 2002.
A Switching Kalman Filter Model for the Motor - Cortical Coding Of (Correct)
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Taylor. D., Tillery, S., Schwartz, A. (2002). Direct cortical control of 3D neuroprosthetic devices. Science, Jun. 7;296(5574):1829-32.
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