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MAX14510EEVB+T

MAX14510EEVB+T

MAX14510EEVB+T

Maxim Integrated

Analog Switch MAX14510 10 Pin 10-UFQFN

SOT-23

MAX14510EEVB+T Datasheet

non-compliant

In-Stock: 0 items
Specifications
Name Value
Type Parameter
Factory Lead Time 6 Weeks
Mount Surface Mount
Mounting Type Surface Mount
Package / Case 10-UFQFN
Number of Pins 10
Operating Temperature -40°C~85°C TA
Packaging Tape & Reel (TR)
Published 2009
Feature USB 2.0
Pbfree Code yes
Part Status Active
Moisture Sensitivity Level (MSL) 1 (Unlimited)
Resistance 5Ohm
Applications Audio, USB
Peak Reflow Temperature (Cel) NOT SPECIFIED
[email protected] Reflow Temperature-Max (s) NOT SPECIFIED
Base Part Number MAX14510
Number of Channels 2
Operating Supply Current 12μA
Throw Configuration DPDT
Supply Type Dual
-3db Bandwidth 950MHz
On-State Resistance (Max) 5Ohm
Multiplexer/Demultiplexer Circuit 2:1, 2:2
Voltage - Supply, Single (V+) 2.7V~5V
RoHS Status ROHS3 Compliant
Pricing & Ordering
Quantity Unit Price Ext. Price
2,500 $1.17932 $2.35864
MAX14510EEVB+T Product Details

MAX14510EEVB+T Overview


It is employed in the way of {0} package.In the {0} package, it is used.It is used as part of the {0} package.It is employed in the way of the {0} package in order to perform its functions.A package called {0} uses it to implement this functionality.An example of its use is in the {0} package.It is used in conjunction with the package {0}.It takes advantage of the {0} package to perform its functions.In order to perform its functions, it utilizes the {0} package.In order to perform its functions, it is employed in the same way as the {0} package.{0} is the recommended mounting type for this part.The recommended mounting type for this part is {0}.This part should be mounted as {0}.It is recommended to mount this part using type {0}.Mounting type {0} is recommended.This part is best mounted with type {0}.A {0} mounting type is recommended for this part.A mounting type of {0} is recommended.For this part, {0} is the recommended mounting type.This part should be mounted with the {0} mounting type.The device has {0} channels on it.{0} channels are available on the device.It has {0} channels.{0} channels are present on the device.In this device, there are {0} channels.{0} channels are on the device.As far as the device is concerned, it has {0} channels.It has a total of {0} channels on it.It appears that the device has only {0} channels available to it.The device has a channel count of {0}.The device is contained within the {0} package.The {0} package contains the device.{0} is the package containing the device.This device is enclosed in the package {0}.{0} is the package that contains the device.{0} is the package in which the device is contained.This device is packaged in {0}.This device can be found within the package {0} which contains the device.Embedded within the {0} package is the device.In the package {0} is the device.It is suitable for a wide range of applications, including {0}.There are a wide variety of applications for it, including {0}.There are many possible applications for it, including {0}.With its versatility and wide range of applications, it is suitable for a wide range of purposes, including {0}.There is a wide variety of applications for which it is suitable, including (0).As a result, it can be used in any number of different applications, including {0}.With its features, it can be used in a wide range of applications, such as {0}.In terms of applications, it is for a wide range of fields, including {0}.It can be applied to a wide range of applications, including {0}.There are a variety of applications for it, including {0}.It varies the range of {0} operating temperature.The range of {0} operating temperatures can be varied.Variations are made to the {0} operating temperature range.Depending on the operating temperature, it varies the range of {0}.A variable range {0} of operating temperatures is provided.Temperatures are varied in the {0} operating range.Depending on the setting, the operating temperature at {0} can be varied.Temperatures can be controlled at {0} according to the setting.It is possible to set the temperature to {0} according to the setting.Depending on the settings, temperatures can be controlled at {0}.The number of terminations on the chip is {0}.There are {0} terminations on the chip.This chip has {0} terminations.{0} terminations are present on the chip.{0} is the number of terminations on the chip.It has {0} terminations.{0} terminations are located on the chip.It is a chip with {0} terminations.This chip has a total of {0} terminations on it.As you can see, there are {0} termination on the chip.This part includes {0} functions for your reference.In this part, you will find {0} functions.Listed below are {0} functions for your reference.In this part, there are {0} functions.You will find in this part {0} functions.For your convenience, this part includes {0} functions.To give you a better understanding of this part, it includes {0} functions.It is for your convenience that this part includes {0} functions.For your convenience, this part includes {0} functions.The {0} functions included in this part are for your convenience.{0} can be found when using this part.Using this part, {0} can be found.This part displays {0}.It is possible to find {0} using this part.When using this part, we can find {0}.If this part is used, {0} will appear.When using this part, it is possible to find {0}.{0} can be found using this part.There is a possibility of finding {0} when using this part.This part allows finding {0}.Please take in mind that this chip should be run at {0}.Make sure this chip is running at {0}.It is important to bear in mind that this chip should be run at {0}.The chip needs to be run at {0}.This chip should always be run at {0}.It is important to remember that this chip should be run at the {0} setting.In order to get the best performance out of this chip, it should be run at {0}.This chip is designed to be run at a {0} voltage level. Please keep this in mind when using it.It is important to take into consideration that this chip should be run at {0}.The chip should be run at a value of {0} so that it can function properly.Its base part number is {0}.{0} is its base part number.The base part number of this item is {0}.This part has the number {0} as its base part number.The base part number is {0}.As far as its part number goes, it is {0}.There is a base part number of {0} for this product.There is a part number {0} assigned to it as its base part number.As far as the base part number is concerned, it is {0}.There is no base part number associated with it.{0} pins are available on the device.There are {0} pins available on the device.An array of {0} pins is present on the device.There are {0} pins available on this device.There are {0} pins on the device.It is possible to use {0} pins on the device.A device with {0} pins is available for use.On the device, there are {0} pins that can be used.A total of {0} pins are available on this device.The device has an available number of {0} pins.To mount this part with {0}.Mounting this part with {0}.Using {0} as the mounting point for this part.{0} is used to mount this part.{0} is recommended for mounting this part.{0} is needed to mount this part.{0} is the mounting point for this part.With {0}, mount this part.With {0} this part can be mounted.{0} is recommended for mounting this part.The sum of the IC chip pins is {0}.There are {0} pins on the IC chip.A chip's pins add up to {0}.It is {0} when the IC chip pins are added up.Each IC chip pin adds up to {0}.There are a total of {0} pins on the IC chip.The sum of the IC chip pins is {0}.The total number of pins on an IC chip is {0}.IC chip pins sum to {0}.There are {0} pins on the IC chip when the pins are added up.It can handle a maximum supply voltage of {0}.A maximum supply voltage of {0} can be handled by it.Voltages up to {0} can be supplied to it.The maximum supply voltage is {0}.Supply voltages of {0} are the maximum it can handle.There is a maximum voltage limit of {0}.{0} is the maximum supply voltage it can handle.This device is capable of handling a maximum supply voltage of {0}.Supply voltages as high as {0} can be handled.Supply voltages up to {0} are supported.It can handle a minimum supply voltage of {0}.Supply voltages as low as {0} can be handled by it.It can operate at a minimum voltage of {0}.It is capable of handling a minimum supply voltage of {0}.Minimum supply voltage is {0}.A voltage of {0} can be used as the minimum supply voltage.Supply voltages of {0} are sufficient for it.There is a minimum supply voltage of {0} that it can handle.This device can handle a minimum supply voltage of {0} without any problems.In order for it to function, it has to be powered by a minimum supply voltage of {0}.The device resistance should stay within the range of {0}.{0} is an ideal range for device resistance.A device's resistance should be within the range of {0}.The resistance of the device should remain within the range of {0}.It is recommended to keep the device's resistance at {0}.There should be a resistance of {0} on the device.Ideally, the device resistance should stay within the range of {0}.It is recommended that the device resistance remain at {0}.It is important that the resistance of the device remain within the range of {0}.It is recommended that the device resistance be maintained within the range of {0}.This part can operate supply current at {0}.The part can be operated at {0} supply current.The supply current for this part can be set to {0}.Using a supply current of {0} will allow this part to operate.When the supply current is at {0}, the part can operate.There is no problem operating this part at {0} supply current.Parts that operate at {0} supply current can be used.It is possible to operate this part with a supply current of {0}.With a supply current of {0}, this part will be able to run.A supply current of {0} can be used with this part in order to make it operate.The device is a part of {0} family.In the {0} family, the device belongs.{0} is the family name of the device.This device belongs to the family of {0}.Family {0} includes the device.This device is a member of the {0} family of devices.It is a part of the family of devices known as {0}.There is a family of devices called {0} which includes this device.This device can be found in the family of {0}.This device falls under the {0} family of devices.{0} is the analog IC that this device employs.The analog IC used in this device is {0}.A device like this uses an analog integrated circuit (IC) called {0}.This device employs an analog IC of type {0}.The analog IC that this device uses is {0}.Analog IC {0} is employed by this device.This device utilizes an analog IC {0}.There is an analog IC called {0} that is used by this device.This device is equipped with an analog integrated circuit (IC) called {0}.The analog IC to which this device is connected is {0}.This chip's operating supply voltage is stated to be at the range of {0}.According to its manufacturer, this chip operates at a voltage of {0}.A voltage of {0} is stated for the operating supply voltage of this chip.A voltage range of {0} is listed for this chip's operating supply voltage.According to its specification, this chip runs on an operating supply voltage of {0}.A {0} operating voltage is specified for this chip.In accordance with its specifications, this chip operates at a supply voltage of {0}.It runs on {0} voltage according to its specification.Chip specifications call for a voltage of {0} for the operating supply.A {0} voltage operating supply voltage is specified for this chip.This part's maximum supply voltage (Vsup) should not be more than {0}.Vsup (supply voltage) should not exceed {0}.The maximum supply voltage of this part (Vsup) should not exceed {0}.In order to ensure that this part is operating properly, its maximum supply voltage (Vsup) should not exceed {0}.Voltage (Vsup) should not exceed {0} for this part.Voltage supply (Vsup) for this part should not exceed {0}.In this part, the maximum supply voltage (Vsup) should not exceed {0}.In order to avoid damage to the part, the maximum supply voltage (Vsup) should not exceed {0}.In order for the part to function properly, the maximum supply voltage (Vsup) should not exceed {0}.There should not be any more than {0} voltage supply for this part.Conduct this part under the dual supply voltage of {0}.The dual supply voltage should be {0}.Ensure that the dual supply voltage is {0}.Conduct this part at {0} dual supply voltage.Under {0}, conduct this part.This part should be operated at dual supply voltage {0}.It is recommended that you conduct this part under the dual supply voltage of {0}.The dual supply voltage should be set to {0} in order to conduct this part.The dual supply voltage must be {0} for this part to be conducted.Ensure the dual supply voltage of {0} is applied to this part.To ensure stable power, it runs dual supply voltage up to {0}.Dual supply voltages up to {0} ensure stable power.In order to ensure stable power, it runs dual supply voltages up to {0}.A dual supply voltage of {0} is used to make sure stable power is provided.With dual supply voltage up to {0}, it ensures stable power.Dual supply voltages are used to ensure stable power up to {0}.The system runs on dual supply voltages up to {0} to ensure stability.Up to {0} voltages are run to ensure stable power.It runs dual supply voltages up to {0} in order to ensure stable power.The unit operates on dual supply voltages up to {0} in order to ensure stable power supply.There are {0} inputs to operate.To operate, there are {0} inputs.Inputs to be operated are {0}.Operating on {0} inputs is possible.Operation requires {0} inputs.It is possible to operate {0} inputs.Operation can be performed on {0} inputs.It is necessary to operate on {0} inputs.A total of {0} inputs are available for operation.To operate, there are only {0} inputs available.It is suggested that it be used at temperatures below {0}.The product should be used at temperatures below {0}.At temperatures below {0}, it is recommended that it be used.Using it below {0} temperatures is recommended.Temperatures below {0} are recommended for its use.A temperature below {0} is recommended for use.Temperatures below {0} should be used.It is recommended to use it at temperatures below [0}.There is a recommendation that it be used at temperatures below [0}.In order to get the best results, it should be utilized at temperatures below {0}.There are {0} outputs on this component.This component has {0} outputs.As far as this component is concerned, there are {0} outputs.{0} outputs are available on this component.It has {0} outputs.A component such as this has {0} outputs.Currently, there are {0} outputs available on this component.On this component, {0} outputs are available.This component has a total of {0} outputs available for use.It is possible for this component to have {0} outputs.To activate this device, the temperature should not be less than {0}.This device must be activated at a temperature greater than {0}.Temperatures below {0} are not suitable for activating this device.The temperature should not be lower than {0} for this device to operate.Activation of this device requires a temperature of at least {0}.It is important that the temperature of the device does not fall below [0}.In order for this device to be activated, the temperature should not be below {0}.This device will not function if the temperature is below {0}.There must be a temperature greater than {0} to activate this device.It is required that the device be activated at a temperature greater than {0}.The maximum supply current (Isup) must not exceed {0}.There must be no more than {0} supply current (Isup).It is prohibited to exceed {0} in terms of supply current (Isup).Current supply (Isup) cannot exceed {0}.If Isup exceeds {0}, the power supply must be turned off.It is forbidden to exceed {0} for the supply current (Isup).Isup cannot exceed {0} as the maximum supply current.Maximum supply current (Isup) must not exceed {0}.Ensure that the maximum supply current (Isup) does not exceed the limit {0}.In order to operate this device, it is essential that the maximum supply current (Isup) not exceed {0}.It has a maximum supply current of {0}.{0} is its maximum supply current.A maximum supply current of {0} is available.A maximum supply current of {0} can be applied to it.There is a maximum supply current of {0}.This device has a maximum supply current of {0}.In terms of supply current, it has a maximum of {0}.A maximum supply current of {0} is available from this device.During normal operation, the maximum current that can be supplied to it is {0}.With a maximum supply current of {0}, it is suitable for use in most applications.The {0} series include this electrical component.Electrical components of the {0} series include this one.Electrical components such as this can be found in the {0} series.There is an electrical component like this in the {0} series.This electrical component is part of the {0} series.Electrical components of this type are included in the {0} series.Among the electrical components included in the {0} series is this one.The {0} series contains this electrical component.This electrical component is included in the series {0}.It is a component of the {0} series.Please keep the following points in mind while you use the device: {0}.In order to maximize the functionality of the device, please keep the following points in mind: {0}.While using the device, you should keep the following points in mind: {0}.When using the device, please keep these things in mind: {0}.As you use the device, please keep the following points in mind: {0}.You should remember the following when using the device: {0}.Keep the following points in mind when using the device: {0}.During the use of the device, please be aware of the following points: {0}It is important that you keep the following things in mind while using the device: {0}.In order to make use of this device as safely as possible, please remember the following points: {0}.

MAX14510EEVB+T Features



MAX14510EEVB+T Applications


There are a lot of Maxim Integrated MAX14510EEVB+T Special Purpose Analog Switches applications.

  • Wind turbines
  • Image denoising
  • Multiplication
  • Packaging
  • Logical circuits
  • Backstop gauging
  • Stagecraft
  • Automation
  • Aerospace
  • Cut-to-length

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