simulink implementation model Search Results


simscape  (MathWorks Inc)
96
MathWorks Inc simscape
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Simscape, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simscape - by Bioz Stars, 2026-06
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matlab simulink  (MathWorks Inc)
96
MathWorks Inc matlab simulink
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Matlab Simulink, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/matlab simulink/product/MathWorks Inc
Average 96 stars, based on 1 article reviews
matlab simulink - by Bioz Stars, 2026-06
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simulink model  (MathWorks Inc)
94
MathWorks Inc simulink model
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Simulink Model, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 94/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/simulink model/product/MathWorks Inc
Average 94 stars, based on 1 article reviews
simulink model - by Bioz Stars, 2026-06
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mode controller simulink block  (MathWorks Inc)
96
MathWorks Inc mode controller simulink block
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Mode Controller Simulink Block, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/mode controller simulink block/product/MathWorks Inc
Average 96 stars, based on 1 article reviews
mode controller simulink block - by Bioz Stars, 2026-06
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simulink environment  (MathWorks Inc)
94
MathWorks Inc simulink environment
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Simulink Environment, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 94/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/simulink environment/product/MathWorks Inc
Average 94 stars, based on 1 article reviews
simulink environment - by Bioz Stars, 2026-06
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mpc toolbox  (MathWorks Inc)
95
MathWorks Inc mpc toolbox
Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab <t>Simscape</t> microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.
Mpc Toolbox, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 95/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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model based design toolbox s32k1xx series nxp embedded system  (MathWorks Inc)
96
MathWorks Inc model based design toolbox s32k1xx series nxp embedded system
Figure 34. Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox <t>S32K1xx</t> Series NXP embedded system for PMSM control.
Model Based Design Toolbox S32k1xx Series Nxp Embedded System, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/model based design toolbox s32k1xx series nxp embedded system/product/MathWorks Inc
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block diagrams  (MathWorks Inc)
92
MathWorks Inc block diagrams
Figure 34. Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox <t>S32K1xx</t> Series NXP embedded system for PMSM control.
Block Diagrams, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 92/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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matlab simulinktm environment  (MathWorks Inc)
96
MathWorks Inc matlab simulinktm environment
Figure 34. Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox <t>S32K1xx</t> Series NXP embedded system for PMSM control.
Matlab Simulinktm Environment, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Average 96 stars, based on 1 article reviews
matlab simulinktm environment - by Bioz Stars, 2026-06
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Image Search Results


Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab Simscape microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.

Journal: The Journal of Neuroscience

Article Title: The Frequency Response of Outer Hair Cell Voltage-Dependent Motility Is Limited by Kinetics of Prestin

doi: 10.1523/JNEUROSCI.0425-18.2018

Figure Lengend Snippet: Electrical configuration of whole-cell and microchamber voltage clamp. A, Whole-cell clamp speed is limited by τ ≈ Rs * Cm. Stray capacitance (amplifier, pipette holder, and pipette) is typically modeled in a position that does not interfere with voltage-clamp speed, but can influence measured high-frequency currents if not compensated. B, The microchamber partitions the cell partway within the orifice of the macropipette. Stray Cs1 is as with whole-cell mode. The frequency response of voltage clamp also depends on Rs and Cm, since stray Cs2, if it contributes at all, is dominated by Cm. The configuration in the figure is for a cell midway in the microchamber, membrane Cm equally divided. At high frequencies, the input capacitance will be the series combination of Cm/2 and Cm/2, giving a value of Cm/4. Thus, τ ≈ Rs * Cm/4 provides a faster clamp than whole cell, but the configuration suffers from lack of DC voltage-clamp control across the membranes. With partitioning of the cell more or less within the chamber, the series combination of the nonequal partitioned cell Cm will provide an input Cm less than the smaller of the two partitioned capacitances, regardless of its location inside or outside the microchamber. Thus, clamp τ for both inserted and extruded membranes will have the same U-shaped speed function, being slowest at the half-inserted condition, as depicted. C, Displayed are two current traces (ta and tb) generated by a Matlab Simscape microchamber model using a voltage protocol similar to our DC off-set AC voltage protocol (Fig. 10B, inset). The red trace (also marked with a downward red triangle) is at zero offset, and the blue trace (also marked with an upward blue triangle) is at an offset of −65 mV. Black lines are single exponential fits. Under voltage clamp, the time course of capacitive currents mirrors the time course of the voltage delivered to the cell membrane, as shown in D and E. See text for more details.

Article Snippet: Models were implemented in Matlab Simulink and Simscape, as detailed previously ( Song and Santos-Sacchi, 2013 ; Santos-Sacchi and Song, 2014 ).

Techniques: Transferring, Generated

Figure 34. Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox S32K1xx Series NXP embedded system for PMSM control.

Journal: Electronics

Article Title: Sensorless Fractional Order Control of PMSM Based on Synergetic and Sliding Mode Controllers

doi: 10.3390/electronics9091494

Figure Lengend Snippet: Figure 34. Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox S32K1xx Series NXP embedded system for PMSM control.

Article Snippet: Software block diagram of the implementation in MATLAB/Simulink and Model-Based Design Toolbox S32K1xx Series NXP embedded system for PMSM control. . t r l i i l i i / i li l t l. Figure 35 presents the block diagram of the software for the outer speed control loop MATLAB/Simulink model utilizing the bit accurate models for the Automotive Math and Motor Control Library Set for NXP S32K14x devices.

Techniques: Software, Blocking Assay, Control