Analog Devices Inc. ADHV4702-1BCPZ
- Part No.:
- ADHV4702-1BCPZ
- Manufacturer:
- Analog Devices Inc.
- Category:
- Instrumentation, Op Amps, Buffer Amps
- Package:
- 12-WQFN Exposed Pad, CSP
- Datasheet:
-
ADHV4702-1BCPZ.pdf
- Description:
- IC OPAMP GP 1 CIRCUIT 12LFCSP
- Quantity:
- Payment:

- Shipping:

Inventory:246
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Product details
Overview
ADHV4702-1BCPZ from Analog Devices Inc. is a high-voltage precision operational amplifier designed for industrial instrumentation, automatic test equipment (ATE), programmable power systems, piezo drivers, and high-voltage analog signal-conditioning applications. The device combines wide supply-voltage capability, high output drive performance, precision analog characteristics, and integrated protection functionality suitable for demanding high-voltage analog systems.
As part of the Analog Devices high-voltage amplifier portfolio, ADHV4702-1BCPZ integrates precision op amp performance with robust high-voltage operation for industrial, medical, instrumentation, and laboratory electronics. For engineers reviewing the ADHV4702-1BCPZ datasheet, ADHV4702-1BCPZ pinout, ADHV4702-1BCPZ application, or ADHV4702-1BCPZ equivalent, this device is widely used in high-voltage DAC buffering, programmable instrumentation, piezoelectric actuator control, semiconductor test systems, and precision industrial analog platforms.
Technical Context
In high-voltage analog systems, ADHV4702-1BCPZ operates as a precision operational amplifier capable of driving higher voltage outputs than conventional low-voltage op amps. The amplifier supports precision amplification, buffering, filtering, and control-loop operation within industrial and instrumentation architectures.
The device is optimized for applications requiring both analog precision and extended output-voltage swing capability. Integrated protection structures and robust output-drive capability help improve reliability when driving capacitive, inductive, or high-voltage loads.
ADHV4702-1BCPZ is commonly used in semiconductor ATE systems, programmable laboratory equipment, industrial automation hardware, high-voltage data-acquisition systems, medical instrumentation, and precision actuator-control platforms.
Key Specifications
| Parameter | Value and Actual Design Meaning |
|---|---|
| Amplifier Type | High-voltage precision operational amplifier for industrial analog systems. |
| Wide Supply Capability | Supports high-voltage analog operation beyond standard low-voltage op amp ranges. |
| Precision Analog Performance | Low offset and stable analog behavior support accurate signal conditioning. |
| High Output Drive | Capable of driving demanding analog loads and high-voltage output stages. |
| Integrated Protection Features | Improves operational reliability in industrial and instrumentation environments. |
| Capacitive Load Support | Supports stable operation with capacitive and actuator-style loads. |
| LFCSP Package | Compact thermally efficient package supporting dense analog PCB layouts. |
Pinout & Package
The ADHV4702-1BCPZ pinout is optimized for high-voltage analog PCB layouts and includes amplifier inputs, output nodes, compensation connections, enable functionality, supply rails, and thermal grounding structures.
For PCB implementation, high-voltage spacing, thermal copper design, low-noise grounding, stable bypass filtering, and separation between high-voltage and low-level analog signals help maintain amplifier stability and operational safety.
| Pin / Function | PCB Design and Circuit Role |
|---|---|
| OUT | High-voltage analog output supporting precision signal drive applications. |
| +IN | Noninverting analog input supporting signal amplification and buffering. |
| -IN | Inverting input supporting feedback and precision gain control. |
| ENABLE | Control input supporting amplifier enable and power management functions. |
| VS+ / VS- | High-voltage supply rails supporting wide-range amplifier operation. |
| EPAD / GND | Thermal and grounding structure supporting heat dissipation and analog stability. |
Key Features
- High-voltage precision operational amplifier architecture.
- Wide supply-voltage capability supports industrial analog systems.
- Precision analog performance suitable for instrumentation applications.
- Strong output-drive capability supports demanding analog loads.
- Integrated protection improves operational robustness.
- Compact LFCSP package supports high-density PCB integration.
Applications
| Automatic Test Equipment (ATE) | Programmable Laboratory Instruments |
|---|---|
|
Use Scenario: Semiconductor testers, industrial validation systems, and automated measurement platforms. IC Role: ADHV4702-1BCPZ performs precision high-voltage signal amplification and buffering. Use Value: Supports accurate measurement control and stable high-voltage analog operation. |
Use Scenario: Programmable power supplies, waveform generators, and laboratory instrumentation. IC Role: Provides high-voltage analog output drive and precision signal conditioning. Use Value: Improves analog accuracy and output-drive flexibility. |
| Piezo & Actuator Control Systems | Industrial Analog Platforms |
|
Use Scenario: Piezoelectric drivers, actuator-control systems, and motion-control electronics. IC Role: Drives capacitive and high-voltage analog loads. Use Value: Supports stable actuator control and high-voltage precision performance. |
Use Scenario: Industrial automation, high-voltage DAC systems, and analog control platforms. IC Role: Performs precision amplification and signal buffering within industrial analog architectures. Use Value: Enhances reliability and precision in high-voltage analog systems. |
Equivalent & Alternatives
When evaluating ADHV4702-1BCPZ equivalent devices, engineers should compare supply-voltage capability, output-drive performance, slew rate, capacitive-load stability, thermal behavior, and precision analog characteristics.
| Alternative Part | Technical Difference | Application Difference | Selection Advice |
|---|---|---|---|
| OPA454 | Texas Instruments high-voltage op amp with different bandwidth and output-drive characteristics. | Used in industrial instrumentation and programmable high-voltage systems. | Choose ADHV4702-1BCPZ for modern Analog Devices high-voltage precision architectures. |
| PA95 | Apex Microtechnology high-voltage amplifier optimized for higher-power analog drive applications. | Commonly used in actuator control and industrial power analog systems. | Choose ADHV4702-1BCPZ for compact precision analog integration and instrumentation-focused performance. |
Compared with OPA454, ADHV4702-1BCPZ is optimized for precision high-voltage instrumentation and compact industrial analog integration. ADHV4702-1BCPZ vs PA95 selection depends on output-drive requirements, power dissipation, bandwidth targets, and high-voltage analog-system architecture objectives.
Quality
ADHV4702-1BCPZ should be sourced as original Analog Devices components through traceable and controlled supply channels. Quality verification procedures may include package inspection, top-mark validation, solderability testing, offset verification, output-drive characterization, thermal testing, and incoming inspection according to high-voltage analog-system production requirements.
Because the device operates in high-voltage analog environments, controlled PCB creepage spacing, thermal management, stable supply bypassing, optimized grounding, and proper high-voltage routing help maintain amplifier reliability and long-term operational stability. Traceable sourcing supports industrial manufacturing quality and reduces counterfeit supply-chain risk.
Availability
ADHV4702-1BCPZ available at Aetrix Electronics and suitable for industrial instrumentation, programmable power systems, semiconductor test equipment, piezo control platforms, and high-voltage analog architectures requiring stable component supply and repeatable production support.
Supply support may include scheduled delivery planning, volume procurement support, BOM continuity assistance, traceable sourcing management, and long-term availability support for OEM manufacturers, instrumentation developers, industrial-system designers, and electronics production programs.
For production deployment, confirming package type, supply-voltage requirements, thermal specifications, output-drive capability, and sourcing continuity helps reduce procurement risk and improve manufacturing stability.
Manufacturer
Analog Devices Inc. is a semiconductor manufacturer specializing in analog ICs, mixed-signal technologies, precision amplifiers, RF devices, power-management solutions, and signal-chain technologies for industrial, medical, communication, aerospace, and instrumentation applications.
The Analog Devices high-voltage amplifier portfolio focuses on precision analog performance, robust output drive, thermal stability, and reliable high-voltage operation for industrial automation, programmable instrumentation, medical electronics, and embedded analog-control systems.
FAQ
What is ADHV4702-1BCPZ used for?
ADHV4702-1BCPZ is used for high-voltage analog amplification in automatic test equipment, programmable instruments, piezo drivers, industrial control systems, and precision instrumentation applications.
Where can I find the ADHV4702-1BCPZ datasheet download?
The ADHV4702-1BCPZ datasheet is available from Analog Devices and includes electrical specifications, output-drive characteristics, thermal data, package information, and PCB integration guidance.
What should be considered in ADHV4702-1BCPZ PCB design?
PCB implementation should prioritize high-voltage spacing, thermal copper design, low-noise grounding, stable supply bypassing, and separation between high-voltage and sensitive analog traces.
Can ADHV4702-1BCPZ drive capacitive loads?
Yes. ADHV4702-1BCPZ is designed to support stable operation with capacitive and high-voltage analog loads such as piezoelectric actuators.
What are common ADHV4702-1BCPZ equivalent solutions?
Common equivalent alternatives include OPA454 and PA95 depending on supply-voltage range, output-drive requirements, thermal performance, and industrial analog-system design objectives.
ADHV4702-1BCPZ Specifications
- Product attributes
- Attribute value
- Manufacturer:
- Analog Devices Inc.
- Series:
- -
- Package/Case:
- 12-WQFN Exposed Pad, CSP
- Packaging:
- Tray
- Product Status:
- Active
- Amplifier Type:
- General Purpose
- Number of Circuits:
- 1
- Output Type:
- -
- Slew Rate:
- 74V/µs
- Gain Bandwidth Product:
- -
- -3db Bandwidth:
- 10 MHz
- Current - Input Bias:
- 0.3 pA
- Voltage - Input Offset:
- 150 µV
- Current - Supply:
- 3mA
- Current - Output / Channel:
- 20 mA
- Voltage - Supply Span (Min):
- 24 V
- Voltage - Supply Span (Max):
- 220 V
- Operating Temperature:
- -40°C ~ 85°C
- Grade:
- -
- Qualification:
- -
- Mounting Type:
- Surface Mount
- Supplier Device Package:
- 12-LFCSP (7x7)
ADHV4702-1BCPZ FAQ
1.How can I place an order for ADHV4702-1BCPZ through Aetrix?
Please submit a Request for Quotation (RFQ) for ADHV4702-1BCPZ on Aetrix. Our sales agent will provide a competitive quotation and guide you through the order confirmation once you accept the terms.
2.Are the price and stock information for ADHV4702-1BCPZ reliable?
The price and inventory of ADHV4702-1BCPZ are updated periodically and may fluctuate due to market conditions. Stock and pricing data are typically refreshed every 24 hours. Quotation validity for ADHV4702-1BCPZ is usually 5 days.
3.What payment methods are accepted for ADHV4702-1BCPZ?
We accept Wire Transfer, PayPal, Credit Card, Western Union, MoneyGram, and Escrow for ADHV4702-1BCPZ transactions.
Note: Certain payment methods may incur a processing fee.
4.How is shipping managed for ADHV4702-1BCPZ?
ADHV4702-1BCPZ orders can be shipped via leading logistics carriers, including DHL, UPS, FedEx, TNT, or Registered Mail.
Once your ADHV4702-1BCPZ order is processed, you will receive an email with the shipment details and tracking number.
Note: Tracking information may take up to 24 hours to appear. Express delivery typically takes 3–5 business days.
5.How can I obtain technical support or documentation for ADHV4702-1BCPZ?
For technical support, including ADHV4702-1BCPZ datasheets, pinout diagrams, or application guidance, please contact our engineering support team. They can provide detailed documentation and assistance for your ADHV4702-1BCPZ requirements.
6.How does Aetrix verify that ADHV4702-1BCPZ is sourced from the original manufacturer or authorized distributors?
All ADHV4702-1BCPZ products on Aetrix are procured from qualified distributors and authorized channels. Our dedicated quality assurance team conducts strict verification, including traceability checks and, if necessary, third-party testing. This ensures that ADHV4702-1BCPZ meets industry standards.
7.What is the process for return or replacement of ADHV4702-1BCPZ?
All ADHV4702-1BCPZ units undergo pre-shipment inspection (PSI). If there is an issue with ADHV4702-1BCPZ, returns or replacements are accepted under the following conditions:
1.Quantity discrepancies, incorrect items, or visible external defects (such as breakage or corrosion), acknowledged by Aetrix.
2.The issue is reported within 90 days of delivery.
3.The ADHV4702-1BCPZ part is unused and in its original packaging.
Return procedure for ADHV4702-1BCPZ:
1.Submit a request within 90 days.
2.Obtain a Return Material Authorization (RMA) from Aetrix.
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