ROHM TLR377GYZ High Precision Rail-to-Rail Input and Output CMOS Amplifier
Product Specifications
- Product Name: ROHM Solution Simulator
- Type: Ultra Small Package & High Precision Rail-to-Rail Input/Output CMOS Operational Amplifier
Product Usage Instructions
Simulation Schematic
This product simulates the frequency response with an Op-Amp as a voltage follower. You can observe the AC gain and phase of the ratio of output to input voltage when the input source voltage AC frequency is changed.
How to Simulate
The simulation settings, such as parameter sweep or convergence options, are configurable from the ‘Simulation Settings’ as shown in Figure 2. Table 1 shows the default setup of the simulation.
Simulation Conditions
Table 2 lists the simulation condition parameters, including instance name, type, parameters, default values, variable range, and units.
Op-Amp Model
Table 3 shows the model pin function implemented for the Op-Amp simulation. The Op-Amp model is a behavioral model for its input/output characteristics.
Peripheral Components
Bill of Materials
Table 4 shows the list of components used in the simulation schematic, including resistors and capacitors with their default values and variable ranges.
Capacitor Equivalent Circuits
The product includes a property editor and an equivalent circuit for capacitors. The default value of ESR is 2mΩ.
INTRODUCTION
- This circuit simulates the frequency response with an Op-Amp as a voltage follower. You can observe the AC gain and phase of the ratio of output to input voltage when the input source voltage AC frequency is changed. You can customize the parameters of the components shown in blue, such as VSOURCE, or peripheral components, and simulate the voltage follower with the desired operating condition.
- You can simulate the circuit in the published application note: Operational amplifier, Comparator (Tutorial). [JP] [EN] [CN] [KR]
General Cautions
- Caution 1: The values from the simulation results are not guaranteed. Please use these results as a guide for your design.
- Caution 2: These model characteristics are specifically at Ta=25°C. Thus, the simulation result with temperature variances may significantly differ from the result with the one done at the actual application board (actual measurement).
- Caution 3: Please refer to the Application Note of Op-Amps for details of the technical information.
- Caution 4: The characteristics may change depending on the actual board design and ROHM strongly recommend to double check those characteristics with actual board where the chips will be mounted on.
Simulation Schematic
How to simulate
- The simulation settings, such as parameter sweep or convergence options, are configurable from the ‘Simulation Settings’ shown in Figure 2, and Table 1 shows the default setup of the simulation.
- In case of simulation convergence issue, you can change advanced options to solve. The temperature is set to 27 °C in the default statement in ‘Manual Options’. You can modify it.
Parameters Default Note Simulation Type Frequency-Domain Do not change Simulation Type Start Frequency 0 Hz Simulate the frequency response for the frequency range from 0 Hz to 100 MHz. End Frequency 100Meg Hz Advanced options Balanced – Convergence Assist – Manual Options .temp 27 –
Simulation Conditions
| Instance Name | Type | Parameters | Default Value | Variable Range | Units | |
| Min | Max | |||||
|
VSOURCE |
Voltage Source |
Voltage_level | 2.5 | 0 | 5.5 | V |
| AC_magnitude | 180 | free | mV | |||
| AC_phase | 0.0 | fixed | ° | |||
|
VDD |
Voltage Source For Op-Amp | Voltage_level | 5 | 1.8(Note1) | 5.5(Note1) | V |
| AC_magnitude | 0.0 | fixed | V | |||
| AC_phase | 0.0 | fixed | ° | |||
|
SDNB |
Voltage Source
For Shutdown Setting |
Voltage_level | 5 | VSS | VDD | V |
| AC_magnitude | 0.0 | fixed | V | |||
| AC_phase | 0.0 | fixed | ° | |||
Op-Amp model
Table 3 shows the model pin function implemented. Note that the Op-Amp model is the behavioral model for its input/output characteristics, and neither protection circuits nor functions unrelated to the purpose are implemented.
| Pin Name | Description |
| +IN | Non-inverting input |
| -IN | Inverting input |
| VDD | Positive power supply |
| VSS | Negative power supply / Ground |
| OUT | Output |
| SDNB | Shutdown setting |
Peripheral Components
Bill of Materials
Table 4 shows the list of components used in the simulation schematic. Each of the capacitors has the parameters of equivalent circuit shown below. The default values of equivalent components are set to zero except for the ESR of C. You can modify the values of each component.
| Type | Instance Name | Default Value | Variable Range | Units | |
| Min | Max | ||||
| Resistor | R1_1 | 0 | 0 | 10 | kΩ |
| RL1 | 10k | 1k | 1M, NC | Ω | |
| Capacitor | C1_1 | 0.1 | 0.1 | 22 | pF |
| CL1 | 10 | free, NC | pF | ||
Capacitor Equivalent Circuits
The default value of ESR is 2 mΩ.
(Note 2) These parameters can take any positive value or zero in simulation, but it does not guarantee the operation of the IC in any condition. Refer to the datasheet to determine the adequate value of parameters.
Recommended Products
Op-Amp
TLR377GYZ: Ultra Small Package & High Precision Rail-to-Rail Input/Output CMOS Operational Amplifier. [JP] [EN] [CN] [KR] [TW] [DE]
Technical Articles and Tools can be found in the Design Resources on the product web page.
Notice
- The information contained in this document is intended to introduce ROHM Group (hereafter referred to as ROHM) products. When using ROHM products, please verify the latest specifications or datasheets before use.
- ROHM products are designed and manufactured for use in general electronic equipment and applications (such as Audio Visual equipment, Office Automation equipment, telecommunication equipment, home appliances, amusement devices, etc.) or specified in the datasheets. Therefore, please contact the ROHM sales representative before using ROHM products in equipment or devices requiring extremely high reliability and whose failure or malfunction may cause danger or injury to human life or body or other serious damage (such as medical equipment, transportation, traffic, aircraft, spacecraft, nuclear power controllers, fuel control, automotive equipment including car accessories, etc. hereafter referred to as Specific Applications). Unless otherwise agreed in writing by ROHM in advance, ROHM shall not be in any way responsible or liable for any damages, expenses, or losses incurred by you or third parties arising from the use of ROHM Products for Specific Applications.
- Electronic components, including semiconductors, can fail or malfunction at a certain rate. Please be sure to implement, at your responsibility, adequate safety measures, including but not limited to fail-safe design against physical injury, and damage to any property, which a failure or malfunction of products may cause.
- The information contained in this document, including application circuit examples and their constants, is intended to explain the standard operation and usage of ROHM products. It is not intended to guarantee, either explicitly or implicitly, the operation of the product in the actual equipment it will be used in. As a result, you are solely responsible for it, and you must exercise your independent verification and judgment in the use of such information contained in this document. ROHM shall not be in any way responsible or liable for any damages, expenses, or losses incurred by you or third parties arising from the use of such information.
- When exporting ROHM products or technologies described in this document to other countries, you must abide by the procedures and provisions stipulated in all applicable export laws and regulations, such as the Foreign Exchange and Foreign Trade Act and the US Export Administration Regulations, and follow the necessary procedures under these provisions.
- The technical information and data described in this document, including typical application circuits, are examples only and are not intended to guarantee to be free from infringement of third parties intellectual property or other rights. ROHM does not grant any license, express or implied, to implement, use, or exploit any intellectual property or other rights owned or controlled by ROHM or any third parties concerning the information contained herein.
- No part of this document may be reprinted or reproduced in any form by any means without the prior written consent of ROHM.
- All information contained in this document is current as of the date of publication and subject to change without notice. Before purchasing or using ROHM products, please confirm the latest information with the ROHM sales representative.
- ROHM does not warrant that the information contained herein is error-free. ROHM shall not be in any way responsible or liable for any damages, expenses, or losses incurred by you or third parties resulting from errors contained in this document.
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FAQ
- Can I customize the parameters of the components in the simulation?
Yes, you can customize parameters such as VSOURCE and peripheral components to simulate the voltage follower with desired operating conditions. - What is the default simulation type and frequency range?
The default simulation type is Frequency-Domain, and the frequency range simulated is from 0 Hz to 100 MHz.
Documents / Resources
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ROHM TLR377GYZ High Precision Rail-to-Rail Input and Output CMOS Amplifier [pdf] User Guide TLR377GYZ, TLR377GYZ High Precision Rail-to-Rail Input and Output CMOS Amplifier, High Precision Rail-to-Rail Input and Output CMOS Amplifier, Rail-to-Rail Input and Output CMOS Amplifier, Input and Output CMOS Amplifier, CMOS Amplifier |
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ROHM TLR377GYZ High Precision Rail-to-Rail Input and Output CMOS Amplifier [pdf] User Guide TLR377GYZ, TLR377GYZ High Precision Rail-to-Rail Input and Output CMOS Amplifier, High Precision Rail-to-Rail Input and Output CMOS Amplifier, Rail-to-Rail Input and Output CMOS Amplifier, Input and Output CMOS Amplifier, CMOS Amplifier |