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A MOS relay offers superior performance to an electromechanical relay in many applications. It is a solid-state device that replaces a coil-activated mechanical switch with an optically isolated input stage driving a MOS. Internally, a MOS relay includes an input-side LED and an output side with a photodiode dome array (PDA), a control circuit, and an output FET block.

1.Coil Designation

Single side stable type 1 coil latching type 2 coil latching type
Non-polarized Polarized 4-terminal 3-terminal

A black coil represents the energized state. For latching relays, schematic diagrams generally show the coil in its reset state. Therefore, the coil symbol is also shown for the reset coil in its reset state.

2.Nominal Coil Voltage (Rated Coil Voltage)

A single value (or narrow range) of source voltage intended by design to be applied to the coil or input.

3.Nominal Operating Current

The value of current flow in the coil when nominal voltage is impressed on the coil

4.Nominal Operating Power

The value of power used by the coil at nominal voltage. For DC coils expressed in watts; AC expressed as volt amperes. Nominal Power (W or VA) = Nominal Voltage × Nominal Current.

5.Coil Resistance

This is the DC resistance of the coil in DC type relays for the temperature conditions listed in the catalog. (Note that for certain types of relays, the DC resistance may be for temperatures other than the standard 20°C 68°F.)

6.Pick-Up Voltage (Pull-In Voltage or Must Operate Voltage)

As the voltage on an unoperated relay is increased, the value at or below which all contacts must function (transfer).

7.Drop-Out Voltage (Release or Must Release Voltage)

As the voltage on an operated relay is decreased, the value at or above which all contacts must revert to their unoperated position.

8.Maximum Applied Voltage

The maximum voltage that can be applied continuously to the coil without causing damage. Short duration spikes of a higher voltage may be tolerable, but this should not be assumed without first checking with the manufacturer.

1. Contact Forms

Denotes the contact mechanism and number of contacts in the contact circuit.

2.Contact Symbols

Form A contacts (normally open contacts)
Form B contacts (normally closed contacts)
Form C contacts (changeover contacts)

Form A contacts are also called N.O. contacts or make contacts. Form B contacts are also called N.C. contacts or break contacts. Form C contacts are also called changeover contacts or transfer contacts.

3.MBB Contacts

Abbreviation for make-before-break contacts. Contact mechanism where Form A contacts (normally open contacts) close before Form B contacts open (normally closed contacts).

4.Rated Switching Power

The design value in watts (DC) or volt amperes (AC) which can safely be switched by the contacts. This value is the product of switching voltage x switching current, and will be lower than the maximum voltage and maximum current product.

5.Maximum Switching Voltage

The maximum open circuit voltage which can safely be switched by the contacts. AC and DC voltage maximums will differ in most cases.

6.Maximum Switching Current

The maximum current which can safely be switched by the contacts. AC and DC current maximums may differ.

7.Maximum Switching Power

The upper limit of power which can be switched by the contacts. Care should be taken not to exceed this value.

8.Maximum Switching Capacity

This is listed in the data column for each type of relay as the maximum value of the contact capacity and is an interrelationship of the maximum switching power, maximum switching voltage, and maximum switching current. The switching current and switching voltage can be obtained from this graph. For example, if the switching voltage is fixed in a certain application, the maximum switching current can be obtained from the intersection between the voltage on the axis and the maximum switching power.

Maximum Switching Capacity
Example: Using TX relay at a switching voltage of 60V DC, the maximum switching current is 1A. (*Maximum switching capacity is given for a resistive load. Be sure to carefully check the actual load before use.)

9.Minimum Switching Capability

This value is a guideline as to the lowest possible level at which it will be possible for a low level load to allow switching. The level of reliability of this value depends on switching frequency, ambient conditions, change in the desired contact resistance, and the absolute value. Please use a relay with AgPd contacts if your needs analog low level loads, control, or a contact resistance of 100 mΩ or less. We recommend that you verify with one of our sales offices regarding usage.

10.Contact Resistance

This value is the combined resistance of the resistance when the contacts are touching each other, the resistance of the terminals and contact spring. The contact resistance is measured using the voltage-drop method as shown below. The measuring currents are designated.

Test Currents

Rated Contact Current or Switching Current (A) Test Current(mA)
Less than 0.01 1
0.01 or more and less than 0.1 10
0.1 or more and less than 1 100
1 or more 1,000

The resistance can be measured with reasonable accuracy on a YHP 4328A milliohmmeter. In general, for relays with a contact rating of 1A or more, measure using the voltage-drop method at 1A 6V DC.

11.Maximum Carrying Current

The maximum current which after closing or prior to opening, the contacts can safely pass without being subject to temperature rise in excess of their design limit, or the design limit of other temperature sensitive components in the relay (coil, springs, insulation, etc.). This value is usually in excess of the maximum switching current.

12.Capacitance

This value is measured between the terminals at 1kHz and 20°C 68°F.


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A MOS relay offers superior performance to an electromechanical relay in many applications. It is a solid-state device that replaces a coil-activated mechanical switch with an optically isolated input stage driving a MOS. Internally, a MOS relay includes an input-side LED and an output side with a photodiode dome array (PDA), a control circuit, and an output FET block.

1.Coil Designation

Single side stable type 1 coil latching type 2 coil latching type
Non-polarized Polarized 4-terminal 3-terminal

A black coil represents the energized state. For latching relays, schematic diagrams generally show the coil in its reset state. Therefore, the coil symbol is also shown for the reset coil in its reset state.

2.Nominal Coil Voltage (Rated Coil Voltage)

A single value (or narrow range) of source voltage intended by design to be applied to the coil or input.

3.Nominal Operating Current

The value of current flow in the coil when nominal voltage is impressed on the coil

4.Nominal Operating Power

The value of power used by the coil at nominal voltage. For DC coils expressed in watts; AC expressed as volt amperes. Nominal Power (W or VA) = Nominal Voltage × Nominal Current.

5.Coil Resistance

This is the DC resistance of the coil in DC type relays for the temperature conditions listed in the catalog. (Note that for certain types of relays, the DC resistance may be for temperatures other than the standard 20°C 68°F.)

6.Pick-Up Voltage (Pull-In Voltage or Must Operate Voltage)

As the voltage on an unoperated relay is increased, the value at or below which all contacts must function (transfer).

7.Drop-Out Voltage (Release or Must Release Voltage)

As the voltage on an operated relay is decreased, the value at or above which all contacts must revert to their unoperated position.

8.Maximum Applied Voltage

The maximum voltage that can be applied continuously to the coil without causing damage. Short duration spikes of a higher voltage may be tolerable, but this should not be assumed without first checking with the manufacturer.

1. Contact Forms

Denotes the contact mechanism and number of contacts in the contact circuit.

2.Contact Symbols

Form A contacts (normally open contacts)
Form B contacts (normally closed contacts)
Form C contacts (changeover contacts)

Form A contacts are also called N.O. contacts or make contacts. Form B contacts are also called N.C. contacts or break contacts. Form C contacts are also called changeover contacts or transfer contacts.

3.MBB Contacts

Abbreviation for make-before-break contacts. Contact mechanism where Form A contacts (normally open contacts) close before Form B contacts open (normally closed contacts).

4.Rated Switching Power

The design value in watts (DC) or volt amperes (AC) which can safely be switched by the contacts. This value is the product of switching voltage x switching current, and will be lower than the maximum voltage and maximum current product.

5.Maximum Switching Voltage

The maximum open circuit voltage which can safely be switched by the contacts. AC and DC voltage maximums will differ in most cases.

6.Maximum Switching Current

The maximum current which can safely be switched by the contacts. AC and DC current maximums may differ.

7.Maximum Switching Power

The upper limit of power which can be switched by the contacts. Care should be taken not to exceed this value.

8.Maximum Switching Capacity

This is listed in the data column for each type of relay as the maximum value of the contact capacity and is an interrelationship of the maximum switching power, maximum switching voltage, and maximum switching current. The switching current and switching voltage can be obtained from this graph. For example, if the switching voltage is fixed in a certain application, the maximum switching current can be obtained from the intersection between the voltage on the axis and the maximum switching power.

Maximum Switching Capacity
Example: Using TX relay at a switching voltage of 60V DC, the maximum switching current is 1A. (*Maximum switching capacity is given for a resistive load. Be sure to carefully check the actual load before use.)

9.Minimum Switching Capability

This value is a guideline as to the lowest possible level at which it will be possible for a low level load to allow switching. The level of reliability of this value depends on switching frequency, ambient conditions, change in the desired contact resistance, and the absolute value. Please use a relay with AgPd contacts if your needs analog low level loads, control, or a contact resistance of 100 mΩ or less. We recommend that you verify with one of our sales offices regarding usage.

10.Contact Resistance

This value is the combined resistance of the resistance when the contacts are touching each other, the resistance of the terminals and contact spring. The contact resistance is measured using the voltage-drop method as shown below. The measuring currents are designated.

Test Currents

Rated Contact Current or Switching Current (A) Test Current(mA)
Less than 0.01 1
0.01 or more and less than 0.1 10
0.1 or more and less than 1 100
1 or more 1,000

The resistance can be measured with reasonable accuracy on a YHP 4328A milliohmmeter. In general, for relays with a contact rating of 1A or more, measure using the voltage-drop method at 1A 6V DC.

11.Maximum Carrying Current

The maximum current which after closing or prior to opening, the contacts can safely pass without being subject to temperature rise in excess of their design limit, or the design limit of other temperature sensitive components in the relay (coil, springs, insulation, etc.). This value is usually in excess of the maximum switching current.

12.Capacitance

This value is measured between the terminals at 1kHz and 20°C 68°F.


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A MOS relay offers superior performance to an electromechanical relay in many applications. It is a solid-state device that replaces a coil-activated mechanical switch with an optically isolated input stage driving a MOS. Internally, a MOS relay includes an input-side LED and an output side with a photodiode dome array (PDA), a control circuit, and an output FET block.

1.Coil Designation

Single side stable type 1 coil latching type 2 coil latching type
Non-polarized Polarized 4-terminal 3-terminal

A black coil represents the energized state. For latching relays, schematic diagrams generally show the coil in its reset state. Therefore, the coil symbol is also shown for the reset coil in its reset state.

2.Nominal Coil Voltage (Rated Coil Voltage)

A single value (or narrow range) of source voltage intended by design to be applied to the coil or input.

3.Nominal Operating Current

The value of current flow in the coil when nominal voltage is impressed on the coil

4.Nominal Operating Power

The value of power used by the coil at nominal voltage. For DC coils expressed in watts; AC expressed as volt amperes. Nominal Power (W or VA) = Nominal Voltage × Nominal Current.

5.Coil Resistance

This is the DC resistance of the coil in DC type relays for the temperature conditions listed in the catalog. (Note that for certain types of relays, the DC resistance may be for temperatures other than the standard 20°C 68°F.)

6.Pick-Up Voltage (Pull-In Voltage or Must Operate Voltage)

As the voltage on an unoperated relay is increased, the value at or below which all contacts must function (transfer).

7.Drop-Out Voltage (Release or Must Release Voltage)

As the voltage on an operated relay is decreased, the value at or above which all contacts must revert to their unoperated position.

8.Maximum Applied Voltage

The maximum voltage that can be applied continuously to the coil without causing damage. Short duration spikes of a higher voltage may be tolerable, but this should not be assumed without first checking with the manufacturer.

1. Contact Forms

Denotes the contact mechanism and number of contacts in the contact circuit.

2.Contact Symbols

Form A contacts (normally open contacts)
Form B contacts (normally closed contacts)
Form C contacts (changeover contacts)

Form A contacts are also called N.O. contacts or make contacts. Form B contacts are also called N.C. contacts or break contacts. Form C contacts are also called changeover contacts or transfer contacts.

3.MBB Contacts

Abbreviation for make-before-break contacts. Contact mechanism where Form A contacts (normally open contacts) close before Form B contacts open (normally closed contacts).

4.Rated Switching Power

The design value in watts (DC) or volt amperes (AC) which can safely be switched by the contacts. This value is the product of switching voltage x switching current, and will be lower than the maximum voltage and maximum current product.

5.Maximum Switching Voltage

The maximum open circuit voltage which can safely be switched by the contacts. AC and DC voltage maximums will differ in most cases.

6.Maximum Switching Current

The maximum current which can safely be switched by the contacts. AC and DC current maximums may differ.

7.Maximum Switching Power

The upper limit of power which can be switched by the contacts. Care should be taken not to exceed this value.

8.Maximum Switching Capacity

This is listed in the data column for each type of relay as the maximum value of the contact capacity and is an interrelationship of the maximum switching power, maximum switching voltage, and maximum switching current. The switching current and switching voltage can be obtained from this graph. For example, if the switching voltage is fixed in a certain application, the maximum switching current can be obtained from the intersection between the voltage on the axis and the maximum switching power.

Maximum Switching Capacity
Example: Using TX relay at a switching voltage of 60V DC, the maximum switching current is 1A. (*Maximum switching capacity is given for a resistive load. Be sure to carefully check the actual load before use.)

9.Minimum Switching Capability

This value is a guideline as to the lowest possible level at which it will be possible for a low level load to allow switching. The level of reliability of this value depends on switching frequency, ambient conditions, change in the desired contact resistance, and the absolute value. Please use a relay with AgPd contacts if your needs analog low level loads, control, or a contact resistance of 100 mΩ or less. We recommend that you verify with one of our sales offices regarding usage.

10.Contact Resistance

This value is the combined resistance of the resistance when the contacts are touching each other, the resistance of the terminals and contact spring. The contact resistance is measured using the voltage-drop method as shown below. The measuring currents are designated.

Test Currents

Rated Contact Current or Switching Current (A) Test Current(mA)
Less than 0.01 1
0.01 or more and less than 0.1 10
0.1 or more and less than 1 100
1 or more 1,000

The resistance can be measured with reasonable accuracy on a YHP 4328A milliohmmeter. In general, for relays with a contact rating of 1A or more, measure using the voltage-drop method at 1A 6V DC.

11.Maximum Carrying Current

The maximum current which after closing or prior to opening, the contacts can safely pass without being subject to temperature rise in excess of their design limit, or the design limit of other temperature sensitive components in the relay (coil, springs, insulation, etc.). This value is usually in excess of the maximum switching current.

12.Capacitance

This value is measured between the terminals at 1kHz and 20°C 68°F.


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A MOS relay offers superior performance to an electromechanical relay in many applications. It is a solid-state device that replaces a coil-activated mechanical switch with an optically isolated input stage driving a MOS. Internally, a MOS relay includes an input-side LED and an output side with a photodiode dome array (PDA), a control circuit, and an output FET block.

1.Coil Designation

Single side stable type 1 coil latching type 2 coil latching type
Non-polarized Polarized 4-terminal 3-terminal

A black coil represents the energized state. For latching relays, schematic diagrams generally show the coil in its reset state. Therefore, the coil symbol is also shown for the reset coil in its reset state.

2.Nominal Coil Voltage (Rated Coil Voltage)

A single value (or narrow range) of source voltage intended by design to be applied to the coil or input.

3.Nominal Operating Current

The value of current flow in the coil when nominal voltage is impressed on the coil

4.Nominal Operating Power

The value of power used by the coil at nominal voltage. For DC coils expressed in watts; AC expressed as volt amperes. Nominal Power (W or VA) = Nominal Voltage × Nominal Current.

5.Coil Resistance

This is the DC resistance of the coil in DC type relays for the temperature conditions listed in the catalog. (Note that for certain types of relays, the DC resistance may be for temperatures other than the standard 20°C 68°F.)

6.Pick-Up Voltage (Pull-In Voltage or Must Operate Voltage)

As the voltage on an unoperated relay is increased, the value at or below which all contacts must function (transfer).

7.Drop-Out Voltage (Release or Must Release Voltage)

As the voltage on an operated relay is decreased, the value at or above which all contacts must revert to their unoperated position.

8.Maximum Applied Voltage

The maximum voltage that can be applied continuously to the coil without causing damage. Short duration spikes of a higher voltage may be tolerable, but this should not be assumed without first checking with the manufacturer.

1. Contact Forms

Denotes the contact mechanism and number of contacts in the contact circuit.

2.Contact Symbols

Form A contacts (normally open contacts)
Form B contacts (normally closed contacts)
Form C contacts (changeover contacts)

Form A contacts are also called N.O. contacts or make contacts. Form B contacts are also called N.C. contacts or break contacts. Form C contacts are also called changeover contacts or transfer contacts.

3.MBB Contacts

Abbreviation for make-before-break contacts. Contact mechanism where Form A contacts (normally open contacts) close before Form B contacts open (normally closed contacts).

4.Rated Switching Power

The design value in watts (DC) or volt amperes (AC) which can safely be switched by the contacts. This value is the product of switching voltage x switching current, and will be lower than the maximum voltage and maximum current product.

5.Maximum Switching Voltage

The maximum open circuit voltage which can safely be switched by the contacts. AC and DC voltage maximums will differ in most cases.

6.Maximum Switching Current

The maximum current which can safely be switched by the contacts. AC and DC current maximums may differ.

7.Maximum Switching Power

The upper limit of power which can be switched by the contacts. Care should be taken not to exceed this value.

8.Maximum Switching Capacity

This is listed in the data column for each type of relay as the maximum value of the contact capacity and is an interrelationship of the maximum switching power, maximum switching voltage, and maximum switching current. The switching current and switching voltage can be obtained from this graph. For example, if the switching voltage is fixed in a certain application, the maximum switching current can be obtained from the intersection between the voltage on the axis and the maximum switching power.

Maximum Switching Capacity
Example: Using TX relay at a switching voltage of 60V DC, the maximum switching current is 1A. (*Maximum switching capacity is given for a resistive load. Be sure to carefully check the actual load before use.)

9.Minimum Switching Capability

This value is a guideline as to the lowest possible level at which it will be possible for a low level load to allow switching. The level of reliability of this value depends on switching frequency, ambient conditions, change in the desired contact resistance, and the absolute value. Please use a relay with AgPd contacts if your needs analog low level loads, control, or a contact resistance of 100 mΩ or less. We recommend that you verify with one of our sales offices regarding usage.

10.Contact Resistance

This value is the combined resistance of the resistance when the contacts are touching each other, the resistance of the terminals and contact spring. The contact resistance is measured using the voltage-drop method as shown below. The measuring currents are designated.

Test Currents

Rated Contact Current or Switching Current (A) Test Current(mA)
Less than 0.01 1
0.01 or more and less than 0.1 10
0.1 or more and less than 1 100
1 or more 1,000

The resistance can be measured with reasonable accuracy on a YHP 4328A milliohmmeter. In general, for relays with a contact rating of 1A or more, measure using the voltage-drop method at 1A 6V DC.

11.Maximum Carrying Current

The maximum current which after closing or prior to opening, the contacts can safely pass without being subject to temperature rise in excess of their design limit, or the design limit of other temperature sensitive components in the relay (coil, springs, insulation, etc.). This value is usually in excess of the maximum switching current.

12.Capacitance

This value is measured between the terminals at 1kHz and 20°C 68°F.