The document discusses SPICE models for simulating various battery applications and circuits. It includes SPICE models for lithium-ion batteries, nickel-hydrogen batteries, and lead-acid batteries. It demonstrates how to simulate charging and discharging curves for these different battery types by setting model parameters like capacity, number of cells, state of charge, and time scale. The document also provides examples of simulating battery packs with multiple cells in series.
How to Design of Power Management of Hybrid Circuit(Battery and Capacitor) us...Tsuyoshi Horigome
The document describes a Simulink model for simulating the power management of a hybrid circuit containing both a lithium-ion battery and capacitor. It presents the circuit designs for a battery-only system and a hybrid battery-capacitor system. For the hybrid system, the capacitor handles current loads above 4 amps while the battery handles loads below 4 amps. The simulation shows that the hybrid system maintains higher states of charge for both components compared to the battery-only system during a test current loading profile. The conclusion is that a hybrid circuit performs better for current waveforms that change quickly.
The document discusses PSpice simulations of lithium-ion battery circuits and applications. It provides specifications for a 65Wh lithium-ion battery pack, including capacity, rated current, input/output voltages, and charging time. It shows discharge curves from simulations at different discharge rates (0.2C, 0.5C, 1C) compared to measurement data. It also simulates the charge characteristics of the battery pack over time at a charge rate of 0.2C.
Lead-Acid Battery Simplified Simulink Model using MATLAB Tsuyoshi Horigome
This document describes a simplified Simulink model of a lead-acid battery that can be used to simulate charge and discharge characteristics. The model accounts for battery voltage (Vbat) versus state of charge (SOC) and can simulate charge/discharge times at various current rates. It includes example simulations for a 50Ah battery showing charge time, discharge time waves at different discharge rates, and Vbat vs SOC curves. Instructions are provided on adjusting the model for different battery specifications by editing parameters like capacity and number of cells.
This document describes a simplified SPICE behavioral model for lithium-ion batteries. The model allows circuit designers to predict battery runtime and performance by modeling voltage over time at different charge and discharge rates. Key parameters like capacity, state of charge, and number of cells can be adjusted based on battery specifications. Examples are provided to demonstrate modeling charge/discharge times and voltage curves for sample battery configurations.
Nickel-Metal Hydride Battery Simplified Simulink Model using MATLAB Tsuyoshi Horigome
This document describes a simplified Simulink model of a nickel-metal hydride (Ni-MH) battery. The model accounts for key battery characteristics including charge time, discharge time at different current rates, and voltage versus state of charge. It can be customized for different battery specifications by adjusting parameters like capacity and number of cells. Simulation results from the model match characteristics from battery datasheets. The model enables prediction of battery performance for use in circuit design and optimization.
Device Modeling of Li-Ion battery MATLAB/Simulink ModelTsuyoshi Horigome
This document describes a MATLAB/Simulink model of a lithium-ion battery that simulates various characteristics including charge time, discharge time at different current rates, and voltage vs. state of charge. The model uses parameters like capacity, number of cells, initial state of charge, and time scale. It outputs graphs of simulations comparing measurement data to modeled charge/discharge curves and voltage vs. state of charge. The model is intended to simulate battery behavior for use in other system models.
This document describes a simplified SPICE behavioral model for lithium-ion capacitors. The model allows circuit designers to predict performance by simulating charge and discharge times. It represents key capacitor specifications like capacity, ESR, and cutoff voltage. The model is parameterized so designers can adjust it to match real capacitor specifications. Simulations demonstrate how the model reproduces manufacturer charge and discharge time data at different currents.
Electric Double-Layer Capacitor(EDLC) of Simple Model using PSpiceTsuyoshi Horigome
This document describes an electric double-layer capacitor (EDLC) simplified SPICE behavioral model. The model enables circuit designers to predict EDLC performance by simulating charge and discharge times. It represents the EDLC using equivalent circuit components and models voltage over time using analog behavioral modeling. The model is characterized by parameters like rated voltage, initial voltage, capacitance, and ESR that are set based on the EDLC specifications. Sample charge and discharge simulations using the model match measurement data closely.
How to Design of Power Management of Hybrid Circuit(Battery and Capacitor) us...Tsuyoshi Horigome
The document describes a Simulink model for simulating the power management of a hybrid circuit containing both a lithium-ion battery and capacitor. It presents the circuit designs for a battery-only system and a hybrid battery-capacitor system. For the hybrid system, the capacitor handles current loads above 4 amps while the battery handles loads below 4 amps. The simulation shows that the hybrid system maintains higher states of charge for both components compared to the battery-only system during a test current loading profile. The conclusion is that a hybrid circuit performs better for current waveforms that change quickly.
The document discusses PSpice simulations of lithium-ion battery circuits and applications. It provides specifications for a 65Wh lithium-ion battery pack, including capacity, rated current, input/output voltages, and charging time. It shows discharge curves from simulations at different discharge rates (0.2C, 0.5C, 1C) compared to measurement data. It also simulates the charge characteristics of the battery pack over time at a charge rate of 0.2C.
Lead-Acid Battery Simplified Simulink Model using MATLAB Tsuyoshi Horigome
This document describes a simplified Simulink model of a lead-acid battery that can be used to simulate charge and discharge characteristics. The model accounts for battery voltage (Vbat) versus state of charge (SOC) and can simulate charge/discharge times at various current rates. It includes example simulations for a 50Ah battery showing charge time, discharge time waves at different discharge rates, and Vbat vs SOC curves. Instructions are provided on adjusting the model for different battery specifications by editing parameters like capacity and number of cells.
This document describes a simplified SPICE behavioral model for lithium-ion batteries. The model allows circuit designers to predict battery runtime and performance by modeling voltage over time at different charge and discharge rates. Key parameters like capacity, state of charge, and number of cells can be adjusted based on battery specifications. Examples are provided to demonstrate modeling charge/discharge times and voltage curves for sample battery configurations.
Nickel-Metal Hydride Battery Simplified Simulink Model using MATLAB Tsuyoshi Horigome
This document describes a simplified Simulink model of a nickel-metal hydride (Ni-MH) battery. The model accounts for key battery characteristics including charge time, discharge time at different current rates, and voltage versus state of charge. It can be customized for different battery specifications by adjusting parameters like capacity and number of cells. Simulation results from the model match characteristics from battery datasheets. The model enables prediction of battery performance for use in circuit design and optimization.
Device Modeling of Li-Ion battery MATLAB/Simulink ModelTsuyoshi Horigome
This document describes a MATLAB/Simulink model of a lithium-ion battery that simulates various characteristics including charge time, discharge time at different current rates, and voltage vs. state of charge. The model uses parameters like capacity, number of cells, initial state of charge, and time scale. It outputs graphs of simulations comparing measurement data to modeled charge/discharge curves and voltage vs. state of charge. The model is intended to simulate battery behavior for use in other system models.
This document describes a simplified SPICE behavioral model for lithium-ion capacitors. The model allows circuit designers to predict performance by simulating charge and discharge times. It represents key capacitor specifications like capacity, ESR, and cutoff voltage. The model is parameterized so designers can adjust it to match real capacitor specifications. Simulations demonstrate how the model reproduces manufacturer charge and discharge time data at different currents.
Electric Double-Layer Capacitor(EDLC) of Simple Model using PSpiceTsuyoshi Horigome
This document describes an electric double-layer capacitor (EDLC) simplified SPICE behavioral model. The model enables circuit designers to predict EDLC performance by simulating charge and discharge times. It represents the EDLC using equivalent circuit components and models voltage over time using analog behavioral modeling. The model is characterized by parameters like rated voltage, initial voltage, capacitance, and ESR that are set based on the EDLC specifications. Sample charge and discharge simulations using the model match measurement data closely.
This document describes a simplified SPICE behavioral model for lithium-ion batteries. The model characterizes the battery using parameters like capacity and state of charge. It accounts for characteristics like charge/discharge time at different current rates and voltage versus state of charge. Examples are provided to model specific battery specifications and extend the model to multiple battery cells in series.
The document provides specifications and simulation results for a photovoltaic lead-acid battery system. It includes specifications for lead-acid batteries and solar cells, as well as simulation circuits and results for charging the batteries from the solar cells under different weather conditions over 24 hours. Key components are lead-acid batteries from GS YUASA, solar panels from BP Solar, and circuits to regulate charging and prevent overvoltage. Simulations examine effects of solar irradiance on charging time.
Electric Double-Layer Capacitor(EDLC) of Simple Model using LTspiceTsuyoshi Horigome
This document describes an electric double-layer capacitor (EDLC) simplified SPICE behavioral model. The model allows circuit designers to predict EDLC performance by simulating charge and discharge times. It represents the EDLC using equivalent circuit components and models the capacitor voltage over time. The model is characterized by parameters like rated voltage, initial voltage, capacitance, and ESR that are set based on the EDLC specifications. Simulation examples show the model accurately captures the EDLC's measured charge and discharge time characteristics.
This document describes the specifications and discharge/charge characteristics of the BAYSUN Lithium-Ion battery pack PBT-BAT-0001. It has a capacity of 65Wh or 4400mAh, operates between 12.8-16.4V, and can be charged in 5 hours. The document compares the simulated and measured discharge curves of a single cell at rates of 0.2C, 0.5C and 1C, and shows the relationships between state of charge, voltage and charging current over time.
This document provides an equivalent circuit diagram and description of the TB67S149FTG clock controlled unipolar stepping motor driver chip. It includes detailed schematics of the various blocks that make up the chip, including the UPnPC control block, reference voltage selection blocks, and driver output blocks. The document is copyrighted by Siam Bee Technologies and is intended for modeling the chip in LTspice simulation software.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. It provides the model's benefits, features, concept, and how to set parameters based on battery specifications. Examples are given to simulate charge time, discharge time, voltage vs state of charge, and extending the model to multiple cells. Instructions are given on including the model in LTspice simulations.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. It provides details on the model features and parameters, example specifications and simulations of charge/discharge time characteristics and voltage vs state of charge for 1 and 7 cell battery configurations. The model accounts for key battery characteristics and can be customized for different battery specifications.
This document provides a list of battery and capacitor models including lithium ion, nickel hydride, lead-acid, lithium ion capacitor, and electric double-layer capacitor. It also mentions that MATLAB provides a Simulink model of a parameter based system that users can create themselves and includes a simple MATLAB model.
This document describes a simplified SPICE behavioral model for lead-acid batteries. The model accounts for the battery voltage, state of charge characteristic to simulate charge and discharge times under various current rates. The model parameters like capacity, number of cells, and initial state of charge can be adjusted based on the battery specifications. Examples are provided to demonstrate simulating the charge time, discharge time, and voltage-state of charge characteristic of a sample lead-acid battery.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. The model accounts for battery voltage over time during charge and discharge at various current rates. It can be customized for different battery specifications by adjusting a few key parameters like capacity, number of cells, and initial state of charge. Examples are provided demonstrating how to simulate common battery characteristics like charge time, discharge time, and voltage-state of charge relationship using the model.
This document describes a simplified SPICE behavioral model for lead-acid batteries. The model allows circuit designers to simulate battery charge and discharge characteristics. It accounts for voltage versus state of charge and enables predicting battery runtime. Parameters like capacity, number of cells, and initial state of charge can be adjusted based on battery specifications. Simulation examples demonstrate charging, discharging, and voltage profiles for sample lead-acid batteries.
This document provides a device modeling report for a current regulating diode. It includes the part number, manufacturer, and LTspice model. It shows the pin configuration and simulates the regulator current versus voltage characteristics, providing a comparison graph and table between the simulation results and measurements for voltages from 0.5V to 100V. The simulation and measurement results have a maximum percentage error of 4.22%.
This document describes a simplified SPICE behavioral model for lithium-ion capacitors. It includes the benefits of the model, the model features and concept, how to set the model parameters based on capacitor specifications, and an example of simulating charge and discharge time characteristics using a 1000F capacitor with 3.8V rating and comparing the simulation results to measurements.
1. The document discusses Spice models for motors, including stepping motors and DC motors.
2. It provides Spice subcircuit models for various motors that include parameters extracted from measurements of the motor characteristics.
3. The models account for factors such as frequency response, back EMF voltage, torque, and internal voltage dependencies to accurately simulate motor behavior.
This document provides a device modeling report for a solar cell component. It includes the part number, manufacturer, and LTspice IV model. It also contains the equivalent circuit diagram, output characteristics from simulation, the evaluation circuit used in simulation, a comparison graph of measurement and simulation results, and a comparison table of key parameters with less than 1% error between measurement and simulation.
This document describes a simplified SPICE behavioral model for a LiFePO4 battery that can be used to simulate battery charge and discharge characteristics. The model uses parameters like capacity, state of charge, number of cells, and a time scaling factor to represent the battery. Examples of simulations showing the battery's charge time, discharge time, and voltage vs capacity curves at different discharge rates are included to demonstrate the model.
This document summarizes a device modeling report for a solar cell component. It includes the part number and manufacturer, describes an evaluation circuit and DC sweep simulation testing the output characteristics, and provides a comparison graph and table showing good agreement between measured and simulated maximum power, voltage at maximum power, current at maximum power, short circuit current, and open circuit voltage, all within 0.2% error.
This document compares PSpice and LTspice simulations of BJT circuits. It examines the hFE characteristic of a BJT by varying the input current from 10mA to 10A and measuring the ratio of output to input current. It also examines the output characteristic of a BJT by varying the input voltage from 0V to 5V and measuring the output collector current, which increases linearly from 0A to 2.4mA over that range. The document provides circuit schematics and output graphs to demonstrate the simulations in PSpice and LTspice.
SPICE MODEL of TPC8109 (Professional+BDP Model) in SPICE PARKTsuyoshi Horigome
SPICE MODEL of TPC8109 (Professional+BDP Model) in SPICE PARK. English Version is http://www.spicepark.net. Japanese Version is http://www.spicepark.com by Bee Technologies.
The document discusses using PSpice to simulate solar power systems. It provides examples of simulating lithium-ion battery discharge and charge characteristics, as well as a photovoltaic module output. Circuits are presented to simulate a solar cell charging a lithium-ion battery pack, including with constant current control and incorporating 24 hours of solar data. Component models and parameters are specified to enable accurate simulation of the system behavior.
This document describes a simplified SPICE behavioral model for lithium-ion batteries. The model characterizes the battery using parameters like capacity and state of charge. It accounts for characteristics like charge/discharge time at different current rates and voltage versus state of charge. Examples are provided to model specific battery specifications and extend the model to multiple battery cells in series.
The document provides specifications and simulation results for a photovoltaic lead-acid battery system. It includes specifications for lead-acid batteries and solar cells, as well as simulation circuits and results for charging the batteries from the solar cells under different weather conditions over 24 hours. Key components are lead-acid batteries from GS YUASA, solar panels from BP Solar, and circuits to regulate charging and prevent overvoltage. Simulations examine effects of solar irradiance on charging time.
Electric Double-Layer Capacitor(EDLC) of Simple Model using LTspiceTsuyoshi Horigome
This document describes an electric double-layer capacitor (EDLC) simplified SPICE behavioral model. The model allows circuit designers to predict EDLC performance by simulating charge and discharge times. It represents the EDLC using equivalent circuit components and models the capacitor voltage over time. The model is characterized by parameters like rated voltage, initial voltage, capacitance, and ESR that are set based on the EDLC specifications. Simulation examples show the model accurately captures the EDLC's measured charge and discharge time characteristics.
This document describes the specifications and discharge/charge characteristics of the BAYSUN Lithium-Ion battery pack PBT-BAT-0001. It has a capacity of 65Wh or 4400mAh, operates between 12.8-16.4V, and can be charged in 5 hours. The document compares the simulated and measured discharge curves of a single cell at rates of 0.2C, 0.5C and 1C, and shows the relationships between state of charge, voltage and charging current over time.
This document provides an equivalent circuit diagram and description of the TB67S149FTG clock controlled unipolar stepping motor driver chip. It includes detailed schematics of the various blocks that make up the chip, including the UPnPC control block, reference voltage selection blocks, and driver output blocks. The document is copyrighted by Siam Bee Technologies and is intended for modeling the chip in LTspice simulation software.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. It provides the model's benefits, features, concept, and how to set parameters based on battery specifications. Examples are given to simulate charge time, discharge time, voltage vs state of charge, and extending the model to multiple cells. Instructions are given on including the model in LTspice simulations.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. It provides details on the model features and parameters, example specifications and simulations of charge/discharge time characteristics and voltage vs state of charge for 1 and 7 cell battery configurations. The model accounts for key battery characteristics and can be customized for different battery specifications.
This document provides a list of battery and capacitor models including lithium ion, nickel hydride, lead-acid, lithium ion capacitor, and electric double-layer capacitor. It also mentions that MATLAB provides a Simulink model of a parameter based system that users can create themselves and includes a simple MATLAB model.
This document describes a simplified SPICE behavioral model for lead-acid batteries. The model accounts for the battery voltage, state of charge characteristic to simulate charge and discharge times under various current rates. The model parameters like capacity, number of cells, and initial state of charge can be adjusted based on the battery specifications. Examples are provided to demonstrate simulating the charge time, discharge time, and voltage-state of charge characteristic of a sample lead-acid battery.
This document describes a simplified SPICE behavioral model for nickel-metal hydride batteries. The model accounts for battery voltage over time during charge and discharge at various current rates. It can be customized for different battery specifications by adjusting a few key parameters like capacity, number of cells, and initial state of charge. Examples are provided demonstrating how to simulate common battery characteristics like charge time, discharge time, and voltage-state of charge relationship using the model.
This document describes a simplified SPICE behavioral model for lead-acid batteries. The model allows circuit designers to simulate battery charge and discharge characteristics. It accounts for voltage versus state of charge and enables predicting battery runtime. Parameters like capacity, number of cells, and initial state of charge can be adjusted based on battery specifications. Simulation examples demonstrate charging, discharging, and voltage profiles for sample lead-acid batteries.
This document provides a device modeling report for a current regulating diode. It includes the part number, manufacturer, and LTspice model. It shows the pin configuration and simulates the regulator current versus voltage characteristics, providing a comparison graph and table between the simulation results and measurements for voltages from 0.5V to 100V. The simulation and measurement results have a maximum percentage error of 4.22%.
This document describes a simplified SPICE behavioral model for lithium-ion capacitors. It includes the benefits of the model, the model features and concept, how to set the model parameters based on capacitor specifications, and an example of simulating charge and discharge time characteristics using a 1000F capacitor with 3.8V rating and comparing the simulation results to measurements.
1. The document discusses Spice models for motors, including stepping motors and DC motors.
2. It provides Spice subcircuit models for various motors that include parameters extracted from measurements of the motor characteristics.
3. The models account for factors such as frequency response, back EMF voltage, torque, and internal voltage dependencies to accurately simulate motor behavior.
This document provides a device modeling report for a solar cell component. It includes the part number, manufacturer, and LTspice IV model. It also contains the equivalent circuit diagram, output characteristics from simulation, the evaluation circuit used in simulation, a comparison graph of measurement and simulation results, and a comparison table of key parameters with less than 1% error between measurement and simulation.
This document describes a simplified SPICE behavioral model for a LiFePO4 battery that can be used to simulate battery charge and discharge characteristics. The model uses parameters like capacity, state of charge, number of cells, and a time scaling factor to represent the battery. Examples of simulations showing the battery's charge time, discharge time, and voltage vs capacity curves at different discharge rates are included to demonstrate the model.
This document summarizes a device modeling report for a solar cell component. It includes the part number and manufacturer, describes an evaluation circuit and DC sweep simulation testing the output characteristics, and provides a comparison graph and table showing good agreement between measured and simulated maximum power, voltage at maximum power, current at maximum power, short circuit current, and open circuit voltage, all within 0.2% error.
This document compares PSpice and LTspice simulations of BJT circuits. It examines the hFE characteristic of a BJT by varying the input current from 10mA to 10A and measuring the ratio of output to input current. It also examines the output characteristic of a BJT by varying the input voltage from 0V to 5V and measuring the output collector current, which increases linearly from 0A to 2.4mA over that range. The document provides circuit schematics and output graphs to demonstrate the simulations in PSpice and LTspice.
SPICE MODEL of TPC8109 (Professional+BDP Model) in SPICE PARKTsuyoshi Horigome
SPICE MODEL of TPC8109 (Professional+BDP Model) in SPICE PARK. English Version is http://www.spicepark.net. Japanese Version is http://www.spicepark.com by Bee Technologies.
The document discusses using PSpice to simulate solar power systems. It provides examples of simulating lithium-ion battery discharge and charge characteristics, as well as a photovoltaic module output. Circuits are presented to simulate a solar cell charging a lithium-ion battery pack, including with constant current control and incorporating 24 hours of solar data. Component models and parameters are specified to enable accurate simulation of the system behavior.
This document describes a simplified SPICE behavioral model for a LiFePO4 battery that can be used to simulate battery charge and discharge characteristics. The model uses parameters like capacity, state of charge, number of cells, and a time scaling factor to represent the battery. Examples are provided to demonstrate simulating the battery's charge time, discharge time, and voltage versus capacity curves at different discharge rates. The model allows predicting the battery's performance under various conditions without complex electrochemical calculations.
Li-ion Capacitor Model (Simplified Model) PSpice VersionTsuyoshi Horigome
This document describes a simplified SPICE behavioral model for lithium-ion capacitors. The model allows circuit designers to predict performance by simulating charge and discharge times. It represents the capacitor using parameters like capacity, ESR, and state of charge. The document provides examples of using the model, including simulating the charge and discharge curves of a sample 1000F capacitor under 5A current.
Lithium Ion Battery Simplified Simulink Model using MATLABTsuyoshi Horigome
This document describes a simplified Simulink model of a lithium-ion battery. It includes the model features, concept, pin configurations, and examples of simulating charge/discharge time characteristics and voltage vs state of charge curves. The model parameters like capacity, number of cells, state of charge, and time scale can be adjusted. Simulation results are shown for examples of charging, discharging at different rates, and the voltage-capacity relationship matching datasheet specifications. Extending the number of cells in series is also demonstrated.
This document discusses using PSpice to simulate solar power systems. It provides examples of simulating lithium-ion battery charging and discharging characteristics, photovoltaic module output, and a complete 24-hour photovoltaic-battery system including variations in initial state of charge. Models and component specifications are included to allow replication of the simulations.
Device Modeling of Li-Ion battery MATLAB/Simulink ModelTsuyoshi Horigome
This document describes a MATLAB/Simulink model of a lithium-ion battery that simulates the battery's charge and discharge characteristics over time. The model accounts for parameters like battery capacity, state of charge, and number of cells. It can be used to simulate the battery's voltage over time during charging and discharging at different current rates. The document provides the model schematic, explains the modeling concepts, and shows examples of simulation results for charge time, discharge time, and voltage versus state of charge.
This document discusses PSpice simulations of battery circuits using Analog Behavior Models (ABM) in the PSpice library. It provides examples of lithium-ion battery, photovoltaic, and battery charging circuit simulations, including discharge/charge characteristics, effects of solar irradiation levels, and 24-hour simulations of a photovoltaic battery charging system with variations in initial state of charge levels.
Lithium Ion Battery Simplified Simulink Model using MATLABTsuyoshi Horigome
This document provides information on a simplified Simulink model of a lithium-ion battery, including:
- An overview of the model's benefits, features, and concept involving characterizing the battery by parameters like capacity, state of charge, and number of cells.
- Examples of simulating charge/discharge time characteristics and voltage vs. state of charge for a sample 1400mAh battery under different current rates.
- Instructions for extending the model to simulate batteries with multiple cells in series by adjusting the number of cells parameter.
- Simulation settings used for examples of charging, discharging, and plotting voltage vs. state of charge.
Simple Model of Lead-Acid Battery Model using PSpicespicepark
This document describes a simplified SPICE behavioral model for lead-acid batteries. The model allows circuit designers to predict battery runtime and performance by accounting for characteristics like voltage over state of charge. It can be adjusted for different battery specifications by editing parameters provided in datasheets, like capacity and number of cells. The model concept involves characterizing the battery by parameters like capacity and state of charge, and including an analog behavioral model for open-circuit voltage versus state of charge. Examples are provided to demonstrate setting parameters and simulating charge/discharge time characteristics for a sample lead-acid battery specification.
This document describes a PSpice model of a lithium-ion battery. It includes an open circuit voltage (OCV) table relating state of charge (SOC) to voltage. Simulation results show the battery voltage discharging over time at different time scales. Adjusting parameters like the E2 value and cycle factor impact the discharge curve. The model allows simulating charge/discharge cycles and effects of capacity fading over multiple cycles.
Original transistor NPN MJE243 MJE243G JE243G TO 225 Newauthelectroniccom
This document provides specifications for the MJE243G NPN and MJE253G PNP complementary silicon power plastic transistors. The transistors are designed for low power audio amplification and low-current, high-speed switching applications. The document includes maximum ratings, electrical characteristics, thermal characteristics, and package dimensions for the transistors.
Original transistor PNP MJE253 MJE253G JE253G 253G TO 225 NewAUTHELECTRONIC
This document provides specifications for the MJE243G NPN and MJE253G PNP complementary silicon power plastic transistors. The transistors are designed for low power audio amplification and low-current, high-speed switching applications. The document includes maximum ratings, electrical characteristics, thermal characteristics, and package dimensions for the transistors.
This document presents a nickel-metal hydride (Ni-MH) battery model and compares simulation results to measurement data. It describes the specifications of a KAWAZAKI Ni-MH battery pack with 10 cells in series and a capacity of 177 Ah. The document shows discharge and charge characteristics at various current rates, including how battery voltage varies with state of charge during discharge and charge. Simulation results closely match real measurement data, validating the accuracy of the Ni-MH battery pack model.
The document provides design details for a critical conduction mode power factor correction (PFC) circuit. It includes:
1) An introduction describing the need for power factor correction to draw sinusoidal current in phase with input voltage for improved power factor.
2) An application circuit diagram for a 400V/200W PFC circuit using a TB6819AFG controller IC along with component values and simulation parameters.
3) Explanations of techniques used including time scaling to speed up simulations and modeling of a common mode choke coil.
4) An 8-step design process covering the output voltage feedback, output capacitor sizing, inductor, input capacitor, auxiliary winding, current/zero current detection
The document provides design details for a critical conduction mode power factor correction (PFC) circuit using the TB6819AFG controller IC. It includes the application circuit, design specifications, equations for determining component values like the output inductor L1, input capacitor C1, and output capacitor C2. It also describes the use of time scaling to speed up transient simulations and modeling of the common mode choke coil. The steps outlined include selecting the output voltage and feedback circuit, output capacitor, inductance L1, input capacitor C4, auxiliary winding L2, and circuits for current detection and zero current detection.
The document provides design specifications and steps for a critical conduction mode power factor correction (PFC) circuit. It includes an application circuit diagram using a TB6819AFG controller IC along with component values and equations. Time scaling is used to speed up transient simulations in SPICE. Key steps explained are selecting the output voltage and feedback resistors, output capacitor, inductor, input capacitor, auxiliary winding, and circuits for current and zero current detection.
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This document provides an inventory list of MOSFET devices from various manufacturers including Fuji Electric, Hitachi, Infineon, International Rectifier, NEC, Panasonic, ROHM, SANYO, SHINDENGEN, and TOSHIBA. The list includes 585 total MOSFET parts with information on the manufacturer, part number, polarity, model type, and date the device information was last updated. The full document provides additional details on the MOSFET devices in the inventory.
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This document provides an inventory list of 4,071 parts from Spicepark as of July 2013. It includes semiconductor components like diodes, transistors, integrated circuits, as well as passive components, batteries, mechanical parts, motors, and lamps. For each part number, the document specifies the manufacturer, model, thermal characteristics, and last update date. The majority of the parts are rectifier diodes from manufacturers like Fairchild, InterSil, ROHM, and Shindengen.
This document provides a parts inventory list from Spice Park with 4,051 total items. It includes summaries of semiconductor components, passive parts, batteries, mechanical parts, motors, and lamps. The semiconductor section lists different types of diodes, transistors, ICs and other components along with manufacturer details.
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This document discusses simulations of motor drive control using SPICE. It describes AC motor drive control simulation using a concept kit and simple model. It also describes DC and stepping motor drive control simulations using simple models. It provides an introduction to motor drive control device modeling services and includes a Q&A section. Simulation examples are presented for an AC motor model showing current, back-EMF voltage, speed, torque, output power and efficiency characteristics under different load conditions. Parameters for DC motor models are also discussed.
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3. Parameter Settings
C is the amp-hour battery capacity [Ah]
– e.g. C = 0.3, 1.4, or 2.8 [Ah]
NS is the number of cells in series
– e.g. NS=1 for 1 cell battery, NS=2 for 2 cells
battery (battery voltage is double from 1 cell)
SOC is the initial state of charge in percent
– e.g. SOC=0 for a empty battery (0%), SOC=1 for
a full charged battery (100%)
TSCALE turns TSCALE seconds into a second
– e.g. TSCALE=60 turns 60s or 1min into a second,
TSCALE=3600 turns 3600s or 1h into a second,
• From the Li-Ion Battery specification, the model is characterized by setting parameters
C, NS, SOC and TSCALE.
Copyright (C) Bee Technologies 2013 3
Model Parameters:
+ -
U1
LI-ION_BATTERY
SOC = 1
NS = 1
TSCALE = 1
C = 1.4
(Default values)
1.リチウムイオン電池のシンプルモデル
4. • The battery information refer to a battery part number LIR18500 of EEMB BATTERY.
Copyright (C) Bee Technologies 2013 4
+ -
U1
LI-ION_BATTERY
SOC = 1
NS = 1
TSCALE = 60
C = 1.4
Battery capacity is
input as a model
parameter
Nominal Voltage 3.7V
Nominal
Capacity
Typical 1400mAh (0.2C discharge)
Charging Voltage 4.20V±0.05V
Charging Std. Current 700mA
Max Current
Charge 1400mA
Discharge 2800mA
Discharge cut-off voltage 2.75V
1.リチウムイオン電池のシンプルモデル
9. + -
U1
LI-ION_BATTERY
SOC = 1
NS = 4
TSCALE = 60
C = 4.4
• The battery information refer to a battery part number PBT-BAT-0001 of BAYSUN Co., Ltd.
Copyright (C) Bee Technologies 2013 9
The number of cells in
series is input as a
model parameter
Output Voltage DC 12.8~16.4V
Capacity of Approximately 4400mAh
Input Voltage DC 20.5V
Charging Time About 5 hours
Basic Specification
Li-ion needs 4 cells
to reach this
voltage level
1.リチウムイオン電池のシンプルモデル
14. -+
U1
NI-MH_BATTERY
C = 1350M
TSCALE = 1
NS = 1
SOC = 1
C is the amp-hour battery capacity [Ah]
– e.g. C = 0.3, 1.4, or 2.8 [Ah]
NS is the number of cells in series
– e.g. NS=1 for 1 cell battery, NS=2 for 2 cells battery
(battery voltage is double from 1 cell)
SOC is the initial state of charge in percent
– e.g. SOC=0 for a empty battery (0%), SOC=1 for a full
charged battery (100%)
TSCALE turns TSCALE seconds(in the real world) into a
second(in simulation)
– e.g. TSCALE=60 turns 60s or 1min (in the real world)
into a second(in simulation), TSCALE=3600 turns 3600s
or 1h into a second.
• From the Ni-Mh Battery specification, the model is characterized by setting parameters
C, NS, SOC and TSCALE.
Copyright (C) Bee Technologies 2013 14
Model Parameters:
(Default values)
2.ニッケル水素電池のシンプルモデル
15. -+
U1
NI-MH_BATTERY
C = 1350M
TSCALE = 1
NS = 1
SOC = 1
• The battery information refer to a battery part number HF-A1U of SANYO.
Copyright (C) Bee Technologies 2013 15
Battery capacity
[Typ.] is input as a
model parameter
Nominal Voltage 1.2V
Capacity
Typical 1350mAh
Minimum 1250mAh
Charging Current Time 1350mA about 1.1h
Discharge cut-off voltage 1.0V
2.ニッケル水素電池のシンプルモデル
18. C is the amp-hour battery capacity [Ah]
– e.g. C = 1, 50, or 100 [Ah]
NS is the number of cells in series
– e.g. NS=1 for 1 cell battery, NS=2 for 2 cells battery
(battery voltage is double from 1 cell)
SOC is the initial state of charge in percent
– e.g. SOC=0 for a empty battery (0%), SOC=1 for a full
charged battery (100%)
TSCALE turns TSCALE seconds(in the real world) into a
second(in simulation)
– e.g. TSCALE=60 turns 60s or 1min (in the real world)
into a second(in simulation), TSCALE=3600 turns 3600s
or 1h into a second.
• From the Lead-Acid Battery specification, the model is characterized by setting
parameters C, NS, SOC and TSCALE.
Copyright (C) Bee Technologies 2013 18
Model Parameters:
(Default values)
3.鉛蓄電池のシンプルモデル
19. • The battery information refer to a battery part number MSE Series of GS YUASA.
Copyright (C) Bee Technologies 2013 19
Battery capacity
[Typ.] is input as a
model parameter
Nominal Voltage 2.0 [Vdc] /Cell
Capacity 50Ah
Rated Charge 0.1C10A
Voltage Set 2.23 [Vdc] /Cell
Charging Time 24 [hours] @ 0.1C10A
3.鉛蓄電池のシンプルモデル
29. Concept of Simulation PV Li-Ion Battery System in 24hr.
Copyright (C) Bee Technologies 2013 29
Lithium-Ion
Batteries Pack
Photovoltaic
Module
Over Voltage Protection
Circuit
16.8V Clamp Circuit
PBT-BAT-0001 (BAYSUN)
DC12.8~16.4V (4 cells)
4400mAh
SX 330 (BP Solar)
Vmp=16.8V
Pmax=30W
DC/DC
Converter
Vopen= (V)
Vclose= (V)
The model contains 24hr.
solar power data (example).
DC Load
VIN=10~18V
VOUT=5V
VIN = 5V
IIN = 1.5A
Low-Voltage
Shutdown
Circuit
5.太陽光発電システム全体シミュレーション
30. Short-circuit current vs. time characteristics of photovoltaic module SX330 for
24hours as the solar power profile (example) is included to the model.
Copyright (C) Bee Technologies 2013 30
Time
0s 4s 8s 12s 16s 20s 24s
I(X_U1.I_I1)
0A
0.4A
0.8A
1.2A
1.6A
2.0A
SX330
+
U2
SX330_24H_TS3600
The model contains
24hr. solar power data
(example).
5.太陽光発電システム全体シミュレーション
31. PV-Battery System Simulation Circuit
Copyright (C) Bee Technologies 2013 31
Ronof f 1
100dchth
Low-Voltage Shutdown Circuit
DC/DC Converter
DMOD
D1
Voch
16.8Vdc
0
0
batt
0
C1
100n
IC = 16.4
0
pv
+ -
U1
PBT-BAT-0001
TSCALE = 3600
SOC1 = 70
SX330
+
U2
SX330_24H_TS3600
batt1
C3
10n
+
-
+
-
S2
S
VON = 0.7
VOFF = 0.3
ROFF = 10MEG
RON = 0.01
0
0
IN+
IN-
OUT+
OUT-
ecal_Iomax
n*V(%IN+, %IN-)*I(IN)/5
EVALUE
Iomax
0
IN+
IN-
OUT+
OUT-
E2
IF( V(lctrl) > 0.25 ,Lopen ,Lclose)
EVALUE
0
PARAMETERS:
Lopen = 14
Lclose = 15.2
IN+
IN-
OUT+
OUT-
E1
IF(V(batt1)>V(dchth),5,0)
EVALUERonof f
100
Conof f
1n
IC = 5
Lctrl
PARAMETERS:
n = 1
I1
1.5Adc
0
OUT
IN+
IN-
OUT+
OUT-
E3
IF( I(OUT)-V(Iomax) > 0 ,n*V(%IN+, %IN-)*I(IN)/(I(OUT)+1u), 5 )
EVALUE
out_dc
DMOD
D2
Conof f 1
100n
IN-
OUT+
OUT-
IN+
G1
Limit( V(%IN+, %IN-)/0.1, 1m, 5*I(out)/(n*limit(V(%IN+, %IN-),10,25)) )
GVALUE
IN
Solar cell model with
24hr. solar power
data.
Lopen value is load
shutdown voltage.
Lclose value is load
reconnect voltage
Set initial battery
voltage, IC=16.4, for
convergence aid.
SOC1 value is initial
State Of Charge of the
battery, is set as 70%
of full voltage.
7.5W Load
(5Vx1.5A).
Simulation at 15W load, change I1 from 1.5A to 3A
5.太陽光発電システム全体シミュレーション
32. Time
0s 4s 8s 12s 16s 20s 24s
1 V(out_dc) 2 I(IN)
0V
2.5V
5.0V
7.5V
1
400mA
500mA
600mA
2
SEL>>SEL>>
V(X_U1.SOC)
0V
25V
50V
75V
100V
1 V(batt) 2 I(U1:PLUS)
12.5V
15.0V
17.5V
1
>>
-2.0A
0A
2.0A
2
I(pv)
0A
1.0A
Simulation Result (SOC1=100)
C1: IC=16.4
Run to time: 24s (24hours in real world)
Step size: 0.01s
Copyright (C) Bee Technologies 2013 32
PV generated current
Battery current
Battery voltage
Battery SOC
DC/DC input current
DC output voltage
• .Options ITL4=1000
SOC1=100 Fully charged, stop
charging
Battery supplies current when solar
power drops.
PV module charge the battery
Charging time
5.太陽光発電システム全体シミュレーション
33. Time
0s 4s 8s 12s 16s 20s 24s
1 V(out_dc) 2 I(IN)
0V
2.5V
5.0V
7.5V
1
0A
0.5A
1.0A
2
>>
V(X_U1.SOC)
0V
25V
50V
75V
100V
10.152m,69.889)
1 V(batt) 2 I(U1:PLUS)
12.5V
15.0V
17.5V
1
-2.0A
0A
2.0A
2
SEL>>SEL>>
(7.6750,15.199)
(5.1850,14.000)
I(pv)
0A
1.0A
C1: IC=16.4
Run to time: 24s (24hours in real world)
Step size: 0.01s
SKIPBP
Copyright (C) Bee Technologies 2013 33
PV generated current
Battery current
Battery voltage
Battery SOC
DC/DC input current
DC output voltage
• .Options ITL4=1000
SOC1=70
V=Lopen
V=Lclose
Shutdown
Reconnect
Fully charged, stop
charging
Battery supplies current when solar
power drops.
PV module charge the battery
Charging time
5.太陽光発電システム全体シミュレーション
Simulation Result (SOC1=70)
34. Time
0s 4s 8s 12s 16s 20s 24s
1 V(out_dc) 2 I(IN)
0V
2.5V
5.0V
7.5V
1
0A
0.5A
1.0A
2
>>
V(X_U1.SOC)
0V
100V
SEL>>
(12.800m,29.854)
1 V(batt) 2 I(U1:PLUS)
12.5V
15.0V
17.5V
1
-2.0A
0A
2.0A
2
>> (1.6328,14.004)
(7.6150,15.193)
I(pv)
0A
1.0A
Simulation Result (SOC1=30)
C1: IC=15
Run to time: 24s (24hours in real world)
Step size: 0.01s
Total job time = 2s
Copyright (C) Bee Technologies 2013 34
PV generated current
Battery current
Battery voltage
Battery SOC
DC/DC input current
DC output voltage
• .Options ITL4=1000
SOC1=30
V=Lopen
V=Lclose
Shutdown
Reconnect
Fully charged, stop
charging
Battery supplies current when solar
power drops.
PV module charge the battery
Charging time
5.太陽光発電システム全体シミュレーション
35. Time
0s 4s 8s 12s 16s 20s 24s
1 V(out_dc) 2 I(IN)
0V
2.5V
5.0V
7.5V
1
0A
0.5A
1.0A
2
>>
V(X_U1.SOC)
0V
100V
1 V(batt) 2 I(U1:PLUS)
12.5V
15.0V
17.5V
1
-2.0A
0A
2.0A
2
SEL>>SEL>>
(7.6163,15.200)
I(pv)
0A
1.0A
Simulation Result (SOC1=10)
C1: IC=14.4
Run to time: 24s (24hours in real world)
Step size: 0.01s
SKIPBP
Copyright (C) Bee Technologies 2013 35
PV generated current
Battery current
Battery voltage
Battery SOC
DC/DC input current
DC output voltage
• .Options RELTOL=0.01
• .Options ITL4=1000
SOC1=10
V=Lclose
Shutdown
Reconnect
Fully charged, stop
charging
Battery supplies current when solar
power drops.
PV module charge the battery
Charging time
5.太陽光発電システム全体シミュレーション
36. Time
0s 4s 8s 12s 16s 20s 24s
1 V(out_dc) 2 I(IN)
0V
2.5V
5.0V
7.5V
1
0A
1.0A
2.0A
2
>>
V(X_U1.SOC)
0V
25V
50V
75V
100V
1 V(batt) 2 I(U1:PLUS)
12.5V
15.0V
17.5V
1
-2.0A
0A
2.0A
2
SEL>>SEL>>
(20.473,14.003)
(7.6086,15.200)
(3.8973,14.000)
I(pv)
0A
1.0A
Simulation Result (SOC1=100, IL=3A or 15W load)
C1: IC=16.4
Run to time: 24s (24hours in real world)
Step size: 0.001s
Copyright (C) Bee Technologies 2013 36
PV generated current
Battery current
Battery voltage
Battery SOC
DC/DC input current
DC output voltage
• .Options ITL4=1000
SOC1=100 Fully charged, stop
charging
Battery supplies current when solar
power drops.
PV module charge the battery
Charging time
V=Lopen
Shutdown
V=Lopen
Shutdown
5.太陽光発電システム全体シミュレーション
38. Case1: Voltage Source(v1) with LTC3105
Simulation Result • Total elapsed time: 410.938sec. ≈ 7min.
Input Voltage
Output Voltage
VMPPC=0.4V
Input Current
38Copyright (C) Bee Technologies 2013
6.環境発電のシミュレーション
39. Solar Cell Specification
• The information refer to a part number 19_12_93 of CONRAD ELECTRONIC.
PARAMETER VALUE
Pmax (W) 0.400
Vmp (V) 0.500
Imp (A) 0.800
Isc (A) 0.872
Voc (V) 0.580
39Copyright (C) Bee Technologies 2013
6.環境発電のシミュレーション
45. Copyright (C) Bee Technologies 2013 45
Case4: Maximum power point tracking (SOL=30%)
Simulation Result • Total elapsed time: 2082.5sec. ≈ 35min.
Input Voltage
VMPPC =0.500V ---
VMPPC =0.475V ---
Output Voltage
Input Current
6.環境発電のシミュレーション
46. Copyright (C) Bee Technologies 2013 46
7.1 電気二重層キャパシタ
Measurement
Battery Voltage
Charging Current
Simulation
7.2 リチウムイオンキャパシタ
当日説明
電気二重層キャパシタとリチウムイオンキャパシタは、現在、デバイスモデリングサービス
にてご提供中です。