Analog Devices Inc. AD536AKQ
- Part Number:
- AD536AKQ
- Manufacturer:
- Analog Devices Inc.
- Ventron No:
- 3267380-AD536AKQ
- Description:
- IC TRUE RMS/DC CONV 14CDIP
- Datasheet:
- AD536AKQ
Analog Devices Inc. AD536AKQ technical specifications, attributes, parameters and parts with similar specifications to Analog Devices Inc. AD536AKQ.
- Mounting TypeThrough Hole
- Package / Case14-CDIP (0.300, 7.62mm)
- Supplier Device Package14-CERDIP
- PackagingTube
- Part StatusObsolete
- Moisture Sensitivity Level (MSL)3 (168 Hours)
- Voltage - Supply5V~36V ±3V~18V
- Current - Supply1.2mA
- RoHS StatusNon-RoHS Compliant
AD536AKQ Overview
There is a mounting type Through Hole for the device.The voltage supply should be set to 5V~36V ±3V~18V.The product is packaged in a Tube way.In a 14-CDIP (0.300, 7.62mm) unit, it is packaged.Right now, there is a supply of 1.2mA.A supplier device bundle of 14-CERDIP is included with the product.
AD536AKQ Features
Supply voltage of 5V~36V ±3V~18V
AD536AKQ Applications
There are a lot of Rochester Electronics, LLC AD536AKQ applications of RMS to DC converters.
True RMS AC DC Measurements
Process Control
True RMS Digital Multimeters and Panel Meters
Digital Multimeters
Panel Meters
Battery-Powered Instruments
There is a mounting type Through Hole for the device.The voltage supply should be set to 5V~36V ±3V~18V.The product is packaged in a Tube way.In a 14-CDIP (0.300, 7.62mm) unit, it is packaged.Right now, there is a supply of 1.2mA.A supplier device bundle of 14-CERDIP is included with the product.
AD536AKQ Features
Supply voltage of 5V~36V ±3V~18V
AD536AKQ Applications
There are a lot of Rochester Electronics, LLC AD536AKQ applications of RMS to DC converters.
True RMS AC DC Measurements
Process Control
True RMS Digital Multimeters and Panel Meters
Digital Multimeters
Panel Meters
Battery-Powered Instruments
AD536AKQ More Descriptions
True RMS to DC Converter 14-Pin CDIP
IC RMS TO DC CONVERTER 14CERDIP
The AD536A is a complete monolithic integrated circuit that performs true rms-to-dc conversion. It offers performance comparable or superior to that of hybrid or modular units costing much more. The AD536A directly computes the true rms value of any complex input waveform containing ac and dc components. A crest factor compensation scheme allows measurements with 1% error at crest factors up to 7. The wide bandwidth of the device extends the measurement capability to 300 kHz with less than 3 dB errors for signal levels greater that 100 mV. An important feature of the AD536A, not previously available in rms converters, is an auxiliary dB output pin. The logarithm of the rms output signal is brought out to a separate pin to allow the dB conversion, with a useful dynamic range of 60 dB. Using an externally supplied reference current, the 0 dB level can be conveniently set to correspond to any input level from 0.1 V to 2 V rms. The AD536A is laser trimmed to minimize input and output offset voltage, to optimize positive and negative waveform symmetry (dc reversal error), and to provide full-scale accuracy at 7 V rms. As a result, no external trims are required to achieve the rated unit accuracy. The input and output pins are fully protected. The input circuitry can take overload voltages well beyond the supply levels. Loss of supply voltage with the input connected to external circuitry does not cause the device to fail. The output is short-circuit protected. The AD536A is available in two accuracy grades (J and K) for commercial temperature range (0°C to 70°C) applications, and one grade (S) rated for the -55°C to 125°C extended range. The AD536AK offers a maximum total error of ±2 mV ±0.2% of reading, while the AD536AJ and AD536AS have maximum errors of ±5 mV ±0.5% of reading. All three versions are available in a hermetically sealed 14-lead DIP or 10-pin TO-100 metal header package. The AD536AS is also available in a 20-terminal leadless hermetically sealed ceramic chip carrier. The AD536A computes the true root-mean-square level of a complex ac (or ac plus dc) input signal and provides an equivalent dc output level. The true rms value of a waveform is a more useful quantity than the average rectified value because it relates directly to the power of the signal. The rms value of a statistical signal also relates to its standard deviation. An external capacitor is required to perform measurements to the fully specified accuracy. The value of this capacitor determines the low frequency ac accuracy, ripple amplitude, and settling time. The AD536A operates equally well from split supplies or a single supply with total supply levels from 5 V to 36 V. With 1 mA quiescent supply current, the device is well suited for a wide variety of remote controllers and battery-powered instruments. Data Sheet, Rev D, 08/2008
IC RMS TO DC CONVERTER 14CERDIP
The AD536A is a complete monolithic integrated circuit that performs true rms-to-dc conversion. It offers performance comparable or superior to that of hybrid or modular units costing much more. The AD536A directly computes the true rms value of any complex input waveform containing ac and dc components. A crest factor compensation scheme allows measurements with 1% error at crest factors up to 7. The wide bandwidth of the device extends the measurement capability to 300 kHz with less than 3 dB errors for signal levels greater that 100 mV. An important feature of the AD536A, not previously available in rms converters, is an auxiliary dB output pin. The logarithm of the rms output signal is brought out to a separate pin to allow the dB conversion, with a useful dynamic range of 60 dB. Using an externally supplied reference current, the 0 dB level can be conveniently set to correspond to any input level from 0.1 V to 2 V rms. The AD536A is laser trimmed to minimize input and output offset voltage, to optimize positive and negative waveform symmetry (dc reversal error), and to provide full-scale accuracy at 7 V rms. As a result, no external trims are required to achieve the rated unit accuracy. The input and output pins are fully protected. The input circuitry can take overload voltages well beyond the supply levels. Loss of supply voltage with the input connected to external circuitry does not cause the device to fail. The output is short-circuit protected. The AD536A is available in two accuracy grades (J and K) for commercial temperature range (0°C to 70°C) applications, and one grade (S) rated for the -55°C to 125°C extended range. The AD536AK offers a maximum total error of ±2 mV ±0.2% of reading, while the AD536AJ and AD536AS have maximum errors of ±5 mV ±0.5% of reading. All three versions are available in a hermetically sealed 14-lead DIP or 10-pin TO-100 metal header package. The AD536AS is also available in a 20-terminal leadless hermetically sealed ceramic chip carrier. The AD536A computes the true root-mean-square level of a complex ac (or ac plus dc) input signal and provides an equivalent dc output level. The true rms value of a waveform is a more useful quantity than the average rectified value because it relates directly to the power of the signal. The rms value of a statistical signal also relates to its standard deviation. An external capacitor is required to perform measurements to the fully specified accuracy. The value of this capacitor determines the low frequency ac accuracy, ripple amplitude, and settling time. The AD536A operates equally well from split supplies or a single supply with total supply levels from 5 V to 36 V. With 1 mA quiescent supply current, the device is well suited for a wide variety of remote controllers and battery-powered instruments. Data Sheet, Rev D, 08/2008
Popular Search Part Number
Related Keywords
Search Tags
Latest News
-
19 January 2024
The Best Tutorial for ISO3082DWR
Ⅰ. Overview of ISO3082DWRⅡ. Technical parameters of ISO3082DWRⅢ. What are the characteristics of ISO3082DWR?Ⅳ. How does ISO3082DWR work?Ⅴ. ISO3082DWR symbol, footprint and pin configurationⅥ. Layout principles of ISO3082DWRⅦ.... -
22 January 2024
What You Need to Know About the MMBT3904 Transistor
Ⅰ. MMBT3904 descriptionⅡ. What is the pin configuration of MMBT3904?Ⅲ. Specifications of MMBT3904Ⅳ. Typical circuit schematic of MMBT3904Ⅴ. Where is MMBT3904 used?Ⅵ. Absolute maximum ratings of MMBT3904Ⅶ. What... -
22 January 2024
LM317T Voltage Regulator: Functions, Usage, Applications and LM317T vs LM317
Ⅰ. Overview of LM317TⅡ. What functions does LM317T have?Ⅲ. Technical parameters of LM317T voltage regulatorⅣ. Circuit of LM317T voltage regulatorⅤ. What is the difference between LM317T and LM317?Ⅵ.... -
23 January 2024
IRF3205 MOSFET Specifications, Package, Working Principle and Applications
Ⅰ. Overview of IRF3205 MOSFETⅡ. Symbol, footprint and pin configuration of IRF3205 MOSFETⅢ. Specifications of IRF3205 MOSFETⅣ. Package of IRF3205 MOSFETⅤ. Working principle and structure of IRF3205 MOSFETⅥ....
Help you to save your cost and time.
Reliable package for your goods.
Fast Reliable Delivery to save time.
Quality premium after-sale service.