This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and modeling parameters. It then provides simulation results and comparisons to measurements for key characteristics like input-output voltage differential, ripple rejection ratio, and output voltage. The simulations show good agreement with measurements within 1% error for most test cases.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and key electrical parameters used in the PSpice model. Simulation results show the input-output voltage differential is within 0.2% of measured, and ripple rejection ratio matches measured performance. The output characteristic under varying load and input conditions is also modeled within 0.2% accuracy.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and modeling parameters. It then provides simulation results and comparisons to measurements for key characteristics like input-output voltage differential, ripple rejection ratio, and output voltage. The simulations show good agreement with measurements within 1% error for most test cases.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and key electrical parameters used in the PSpice model. Simulation results show the input-output voltage differential is within 0.2% of measured, and ripple rejection ratio matches measured performance. The output characteristic under varying load and input conditions is also modeled within 0.2% accuracy.
This document summarizes the test results of a voltage regulator component. It describes the manufacturer, part number, and PSpice model parameters. It then provides the results of simulating the input-output voltage differential characteristic, ripple rejection ratio, and output characteristic. The simulation results match well with measurements, with less than 1% error in most cases.
This document summarizes the modeling parameters and performance of the uPC78N24H voltage regulator. It includes:
1) A list of model parameters for the regulator including reference voltage, emission coefficient, and capacitance values.
2) Simulation results showing the input-output voltage differential is within 0.2% of measurements.
3) Ripple rejection ratio simulation matching measurements within 5%.
4) Output voltage simulation matching measurements to within 0.05% under varying load and input conditions.
This document summarizes the modeling parameters and performance of the uPC78N08H voltage regulator. It includes:
1) A list of model parameters used in the PSpice model including reference voltage, emission coefficient, and capacitance values.
2) Simulation results showing the input-output voltage differential is within 0.008% of measurements.
3) Ripple rejection ratio simulation of 67.535dB is within -0.684% of measured value.
4) Output characteristic simulation of 7.9796V is within -0.255% of measured 8V output voltage.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and key electrical parameters represented in the PSpice model. Simulation results show the input-output voltage differential is within 0.1% of measured, and ripple rejection ratio is within 0.9% of measured. The output characteristic comparison shows simulation within 0.65% of measured.
This document summarizes the test results of a voltage regulator component. It describes the manufacturer, part number, and PSpice model parameters. It then provides the results of simulating the input-output voltage differential characteristic, ripple rejection ratio, and output characteristic. The simulation results match well with measurements, with less than 1% error in most cases.
This document summarizes the modeling parameters and performance of the uPC78N24H voltage regulator. It includes:
1) A list of model parameters for the regulator including reference voltage, emission coefficient, and capacitance values.
2) Simulation results showing the input-output voltage differential is within 0.2% of measurements.
3) Ripple rejection ratio simulation matching measurements within 5%.
4) Output voltage simulation matching measurements to within 0.05% under varying load and input conditions.
This document summarizes the modeling parameters and performance of the uPC78N08H voltage regulator. It includes:
1) A list of model parameters used in the PSpice model including reference voltage, emission coefficient, and capacitance values.
2) Simulation results showing the input-output voltage differential is within 0.008% of measurements.
3) Ripple rejection ratio simulation of 67.535dB is within -0.684% of measured value.
4) Output characteristic simulation of 7.9796V is within -0.255% of measured 8V output voltage.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and key electrical parameters represented in the PSpice model. Simulation results show the input-output voltage differential is within 0.1% of measured, and ripple rejection ratio is within 0.9% of measured. The output characteristic comparison shows simulation within 0.65% of measured.
This document summarizes the modeling parameters and performance of a voltage regulator component. It describes the manufacturer, part number, and key electrical parameters used in the PSpice model. Simulation results show the input-output voltage differential is within 0.035% of measured, and ripple rejection ratio is within 1.808% of measured. The maximum output voltage error shown in simulation is 0.447% compared to measurement.
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The document provides an inventory update from February 2024 of Spice Park, which contains 6,694 electronic components. It lists the components by type (e.g. semiconductor), part number, manufacturer, thermal rating, and quantity on hand. For example, it shows that there are 621 general purpose rectifier diodes from manufacturers such as Fairchild, Fuji, Intersil, Rohm, Shindengen, and Toshiba. The detailed four-page section provides further information on the first item, general purpose rectifier diodes, including 152 individual part numbers and specifications.
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This document discusses parametric sweeps of external and internal resistance values Rg for circuit simulation in LTspice. It also references outputting a waveform similar to a report on fall time characteristics for a device modeling report with customer Samsung.
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Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-und-domino-lizenzkostenreduzierung-in-der-welt-von-dlau/
DLAU und die Lizenzen nach dem CCB- und CCX-Modell sind für viele in der HCL-Community seit letztem Jahr ein heißes Thema. Als Notes- oder Domino-Kunde haben Sie vielleicht mit unerwartet hohen Benutzerzahlen und Lizenzgebühren zu kämpfen. Sie fragen sich vielleicht, wie diese neue Art der Lizenzierung funktioniert und welchen Nutzen sie Ihnen bringt. Vor allem wollen Sie sicherlich Ihr Budget einhalten und Kosten sparen, wo immer möglich. Das verstehen wir und wir möchten Ihnen dabei helfen!
Wir erklären Ihnen, wie Sie häufige Konfigurationsprobleme lösen können, die dazu führen können, dass mehr Benutzer gezählt werden als nötig, und wie Sie überflüssige oder ungenutzte Konten identifizieren und entfernen können, um Geld zu sparen. Es gibt auch einige Ansätze, die zu unnötigen Ausgaben führen können, z. B. wenn ein Personendokument anstelle eines Mail-Ins für geteilte Mailboxen verwendet wird. Wir zeigen Ihnen solche Fälle und deren Lösungen. Und natürlich erklären wir Ihnen das neue Lizenzmodell.
Nehmen Sie an diesem Webinar teil, bei dem HCL-Ambassador Marc Thomas und Gastredner Franz Walder Ihnen diese neue Welt näherbringen. Es vermittelt Ihnen die Tools und das Know-how, um den Überblick zu bewahren. Sie werden in der Lage sein, Ihre Kosten durch eine optimierte Domino-Konfiguration zu reduzieren und auch in Zukunft gering zu halten.
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- Reduzierung der Lizenzkosten durch Auffinden und Beheben von Fehlkonfigurationen und überflüssigen Konten
- Wie funktionieren CCB- und CCX-Lizenzen wirklich?
- Verstehen des DLAU-Tools und wie man es am besten nutzt
- Tipps für häufige Problembereiche, wie z. B. Team-Postfächer, Funktions-/Testbenutzer usw.
- Praxisbeispiele und Best Practices zum sofortigen Umsetzen
HCL Notes und Domino Lizenzkostenreduzierung in der Welt von DLAU
SPICE MODEL of uPC78M07A in SPICE PARK
1. Device Modeling Report
COMPONENTS : VOLTAGE REGULATOR
PART NUMBER : uPC78M07A
MANUFACTURER : NEC Electronics Corporation
Panasonic
Bee Technologies Inc.
All Rights Reserved Copyright (c) Bee Technologies Inc. 2004
2. MODEL PARAMETER
Pspice
model Model description
parameter
VREF Reference Voltage
N Emission Coefficient
BETA Tranconductance of JFET Transistor
VAF Early Voltage of Output Pass Transistor
CPZ Output Impedance Zero Capacitor
RB2 Base Resistance of Output Limit Voltage Source
ESC1 Coefficient of Current Limit Voltage Source
ESC2 Coefficient of Current Limit Voltage Source
EFB1 Coefficient of Foldback Current Voltage Source
EFB2 Coefficient of Foldback Current Voltage Source
EFB3 Coefficient of Foldback Current Voltage Source
EB Non-ideal Base-Collector Diode Saturation Current
All Rights Reserved Copyright (c) Bee Technologies Inc. 2004
3. Input-Output Voltage Differential Characteristic
Evaluation Circuit
U1
1 3
IN OUT
GND UPC78M07A
2
V1 RL
12 Cout
20
0.1u
0
Simulation result
Input - Output
Input
Example
VIN - VOUT Measurement Simulation % Error
12 (V) – 7 (V) 5 (V) 4.9945 (V) -0.11
All Rights Reserved Copyright (c) Bee Technologies Inc. 2004
4. Ripple Rejection (RR) Characteristic
Evaluation Circuit
U1
Vin Vout
1 3
IN OUT
GND UPC78M07A
2
D1 D2
S1VBA S1VBA C1 Cout RL
0.47u 0.1u 20
V1 D3 D4
VOFF = 0
VAMPL = 1 S1VBA S1VBA
FREQ = 120
V2
13
0
Simulation result
Output
Input
Comparison Table
Measurement Simulation % Error
Ripple rejection ratio
(dB)
82 79.996 -2.444
All Rights Reserved Copyright (c) Bee Technologies Inc. 2004