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Motion Controllers

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Novanta IMS
Motion Controllers
Novanta IMS

Motion Controllers - Novanta IMS

A motion controller is a device engineered to manage the order, speed, location, and force of a mechanical system.

Novanta IMS
Reactors

Reactors

Breaking Resistors

Breaking Resistors

Soft Starters

Soft Starters

Motion Controller Accessories

Motion Controller Accessories

Servo Motor Drives

Servo Motor Drives

Motor Control Starters

Motor Control Starters

Variable Frequency Drives (VFD)

Variable Frequency Drives (VFD)

Novanta IMS

Found 1,377 products

MDO1FSL17B4-N
Novanta IMS

Novanta IMS MDO1FSL17B4-N is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 42x42mm flange mounting mode, designed to operate within an ambient air temperature range of 0 to +85°C. This model includes a rear control knob and a double motor stack in its Plus version, adhering to standard features. It offers a connection through 30cm / 12" bare end flying leads with a 10-pin friction-lock wire crimp connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and operates on a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. The MDO1FSL17B4-N delivers a stall torque of 42N.cm and a moment of inertia of 0.057kg.cm2, with a resolution characterized by a 1.8° step angle.

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MDO1FSD23D6-E5
Novanta IMS

Novanta IMS MDO1FSD23D6-E5 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed with a 57x57mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with an external single-end 500-line optical encoder providing quadruple (4) motor stack Plus version standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and supports a supply voltage range of 12Vdc to 60Vdc, optimally at 24Vdc or 48Vdc. The motor delivers a stall torque of 200N.cm and has a moment of inertia of 0.76kg.cm^2, with a resolution characterized by a 1.8° step angle.

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MDO1FSD23B7-N
Novanta IMS

Novanta IMS MDO1FSD23B7-N is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with a rear control knob and a double motor stack in its Plus version, which includes standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and accepts a supply voltage ranging from 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. The MDO1FSD23B7-N offers a stall torque of 102N.cm and a moment of inertia of 0.26kg.cm^2, with a resolution characterized by a 1.8° step angle.

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MDO1FSD17C4
Novanta IMS

Novanta IMS MDO1FSD17C4 is a stepper motor that features an integrated driver and operates as a 2-phase DC stepper motor with SPI communication. It is designed with a 42x42mm flange for mounting and is suitable for operation in ambient air temperatures ranging from 0 to +85°C. This motor is part of the Stepper motors sub-range and comes in a triple (3) motor stack Plus version, which includes standard features. It offers a connection through 30cm / 12" bare end flying leads with a 10-pin IDC non-locking connector. The MDO1FSD17C4 has an IP20 degree of protection and requires a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. It delivers a stall torque of 53N.cm and has a moment of inertia of 0.082kg.cm^2. The resolution of this motor is defined by a 1.8° step angle.

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MDO1FSD17A4-E6
Novanta IMS

Novanta IMS MDO1FSD17A4-E6 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed with a 42x42mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with an external single-end 1000-line optical encoder and represents the Plus version with standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and requires a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 23N.cm and has a moment of inertia of 0.038kg.cm^2, with a resolution characterized by a 1.8° step angle.

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MDM5PSD23C7
Novanta IMS

Novanta IMS MDM5PSD23C7 is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 57x57mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This model is designed with a triple (3) motor stack, enhanced by a Plus version with differential CW/CCW input. It utilizes a non-locking spring-clamp connector and a 10-pin IDC non-locking connector for connections. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20. The MDM5PSD23C7 operates on a supply voltage ranging from 12Vdc to 75Vdc, with recommended voltages at 24Vdc, 48Vdc, and 72Vdc. It delivers a stall torque of 169N.cm and has a moment of inertia of 0.46kg.cm^2. The resolution is defined by a 1.8° step angle.

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MDM5PSD17C4-EJL
Novanta IMS

Novanta IMS MDM5PSD17C4-EJL is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 42x42mm flange mounting mode and is designed to operate within an ambient air temperature range of 0 to +85°C. This model includes an external differential 1000-line optical encoder with a triple (3) motor stack, enhanced for applications requiring differential CW/CCW input. It utilizes a non-locking spring-clamp connector and a 10-pin IDC non-locking connector for its connections. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and operates on a supply voltage ranging from 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 53N.cm and has a moment of inertia of 0.082kg.cm^2, with a resolution specified as a 1.8° step angle.

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MDM5FSD23B7-E2
Novanta IMS

Novanta IMS MDM5FSD23B7-E2 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This model includes an external single-end 200-line optical encoder with double (2) motor stack and a Plus version with differential CW/CCW input. It offers a connection via 30cm / 12" bare end flying leads with an IDC connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and supports a supply voltage range of 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. The motor delivers a stall torque of 102N.cm and a moment of inertia of 0.26kg.cm^2, with a resolution characterized by a 1.8° step angle.

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MDM5FSD23A7
Novanta IMS

Novanta IMS MDM5FSD23A7 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This model, part of the Stepper motors sub-range, is a single motor stack Plus version that supports differential CW/CCW input. It connects via 30cm / 12" bare end flying leads to an IDC connector. The MDM5FSD23A7 offers a degree of protection rated at IP20 and accepts a supply voltage ranging from 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. It delivers a stall torque of 64N.cm and has a moment of inertia of 0.18kg.cm^2. The resolution is specified as a 1.8° step angle.

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MDM5FSD17B4
Novanta IMS

Novanta IMS MDM5FSD17B4 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 42x42mm flange and operates within an ambient air temperature range of 0 to +85°C. This model, part of the Stepper motors sub-range, showcases a double motor stack Plus version with differential CW/CCW input. It connects via 30cm / 12" bare end flying leads to an IDC connector. With a degree of protection rated at IP20, it supports a supply voltage range of 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 42N.cm and has a moment of inertia of 0.057kg.cm^2. Its resolution is defined by a 1.8° step angle.

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ItemManufacturerPriceStockDelivery

MDO1FSL17B4-N

Novanta IMS MDO1FSL17B4-N is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 42x42mm flange mounting mode, designed to operate within an ambient air temperature range of 0 to +85°C. This model includes a rear control knob and a double motor stack in its Plus version, adhering to standard features. It offers a connection through 30cm / 12" bare end flying leads with a 10-pin friction-lock wire crimp connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and operates on a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. The MDO1FSL17B4-N delivers a stall torque of 42N.cm and a moment of inertia of 0.057kg.cm2, with a resolution characterized by a 1.8° step angle.

Novanta IMS

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MDO1FSD23D6-E5

Novanta IMS MDO1FSD23D6-E5 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed with a 57x57mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with an external single-end 500-line optical encoder providing quadruple (4) motor stack Plus version standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and supports a supply voltage range of 12Vdc to 60Vdc, optimally at 24Vdc or 48Vdc. The motor delivers a stall torque of 200N.cm and has a moment of inertia of 0.76kg.cm^2, with a resolution characterized by a 1.8° step angle.

Novanta IMS

Quick Quote

MDO1FSD23B7-N

Novanta IMS MDO1FSD23B7-N is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with a rear control knob and a double motor stack in its Plus version, which includes standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and accepts a supply voltage ranging from 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. The MDO1FSD23B7-N offers a stall torque of 102N.cm and a moment of inertia of 0.26kg.cm^2, with a resolution characterized by a 1.8° step angle.

Novanta IMS

Quick Quote

MDO1FSD17C4

Novanta IMS MDO1FSD17C4 is a stepper motor that features an integrated driver and operates as a 2-phase DC stepper motor with SPI communication. It is designed with a 42x42mm flange for mounting and is suitable for operation in ambient air temperatures ranging from 0 to +85°C. This motor is part of the Stepper motors sub-range and comes in a triple (3) motor stack Plus version, which includes standard features. It offers a connection through 30cm / 12" bare end flying leads with a 10-pin IDC non-locking connector. The MDO1FSD17C4 has an IP20 degree of protection and requires a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. It delivers a stall torque of 53N.cm and has a moment of inertia of 0.082kg.cm^2. The resolution of this motor is defined by a 1.8° step angle.

Novanta IMS

Quick Quote

MDO1FSD17A4-E6

Novanta IMS MDO1FSD17A4-E6 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed with a 42x42mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This motor is equipped with an external single-end 1000-line optical encoder and represents the Plus version with standard features. It connects via 30cm / 12" bare end flying leads to a 10-pin IDC non-locking connector. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and requires a supply voltage of 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 23N.cm and has a moment of inertia of 0.038kg.cm^2, with a resolution characterized by a 1.8° step angle.

Novanta IMS

Quick Quote

MDM5PSD23C7

Novanta IMS MDM5PSD23C7 is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 57x57mm flange for mounting and operates within an ambient air temperature range of 0 to +85°C. This model is designed with a triple (3) motor stack, enhanced by a Plus version with differential CW/CCW input. It utilizes a non-locking spring-clamp connector and a 10-pin IDC non-locking connector for connections. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20. The MDM5PSD23C7 operates on a supply voltage ranging from 12Vdc to 75Vdc, with recommended voltages at 24Vdc, 48Vdc, and 72Vdc. It delivers a stall torque of 169N.cm and has a moment of inertia of 0.46kg.cm^2. The resolution is defined by a 1.8° step angle.

Novanta IMS

Quick Quote

MDM5PSD17C4-EJL

Novanta IMS MDM5PSD17C4-EJL is a stepper motor characterized by its integrated driver and 2-phase DC stepper motor SPI functionality. It features a 42x42mm flange mounting mode and is designed to operate within an ambient air temperature range of 0 to +85°C. This model includes an external differential 1000-line optical encoder with a triple (3) motor stack, enhanced for applications requiring differential CW/CCW input. It utilizes a non-locking spring-clamp connector and a 10-pin IDC non-locking connector for its connections. As part of the Stepper motors sub-range, it offers a degree of protection rated at IP20 and operates on a supply voltage ranging from 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 53N.cm and has a moment of inertia of 0.082kg.cm^2, with a resolution specified as a 1.8° step angle.

Novanta IMS

Quick Quote

MDM5FSD23B7-E2

Novanta IMS MDM5FSD23B7-E2 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This model includes an external single-end 200-line optical encoder with double (2) motor stack and a Plus version with differential CW/CCW input. It offers a connection via 30cm / 12" bare end flying leads with an IDC connector. As part of the Stepper motors sub-range, it has an IP20 degree of protection and supports a supply voltage range of 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. The motor delivers a stall torque of 102N.cm and a moment of inertia of 0.26kg.cm^2, with a resolution characterized by a 1.8° step angle.

Novanta IMS

Quick Quote

MDM5FSD23A7

Novanta IMS MDM5FSD23A7 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 57x57mm flange and operates within an ambient air temperature range of 0 to +85°C. This model, part of the Stepper motors sub-range, is a single motor stack Plus version that supports differential CW/CCW input. It connects via 30cm / 12" bare end flying leads to an IDC connector. The MDM5FSD23A7 offers a degree of protection rated at IP20 and accepts a supply voltage ranging from 12Vdc to 75Vdc, including 24Vdc, 48Vdc, and 72Vdc options. It delivers a stall torque of 64N.cm and has a moment of inertia of 0.18kg.cm^2. The resolution is specified as a 1.8° step angle.

Novanta IMS

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MDM5FSD17B4

Novanta IMS MDM5FSD17B4 is a stepper motor featuring an integrated driver and a 2-phase DC stepper motor with SPI communication. It is designed for mounting with a 42x42mm flange and operates within an ambient air temperature range of 0 to +85°C. This model, part of the Stepper motors sub-range, showcases a double motor stack Plus version with differential CW/CCW input. It connects via 30cm / 12" bare end flying leads to an IDC connector. With a degree of protection rated at IP20, it supports a supply voltage range of 12Vdc to 48Vdc, optimally at 24Vdc. The motor delivers a stall torque of 42N.cm and has a moment of inertia of 0.057kg.cm^2. Its resolution is defined by a 1.8° step angle.

Novanta IMS

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Motion Controllers

General Guide & Overview

Motion controllers are essential devices in the realm of industrial motion control. They serve as the backbone of precision and automation in various industries, including manufacturing, medicine, entertainment, and research. If you're looking for efficient and reliable solutions to control the sequence, velocity, position, and torque of mechanical systems, motion controllers are the key.

Industrial motion controllers are designed to interpret desired movements or actions and convert them into electrical signals, enabling seamless motion control. These controllers possess command and control logic, input formats, processing power, output signals, feedback systems, drive interfaces, and diverse types of motion.

The advantages of motion controllers are numerous. They offer precision and accuracy in executing complex movement patterns, ensuring the system follows the desired path and reaches specific positions. With real-time adjustments and automated sequences, motion controllers eliminate manual errors and optimize speed and efficiency. They also provide versatility, adapting to different types of motion and applications. Safety is enhanced through continuous monitoring and the ability to initiate corrective actions. Moreover, motion controllers offer integration capabilities, seamlessly working with other system components to provide centralized control.

However, it's important to be aware of the challenges and considerations associated with motion controllers. The complexity of advanced setup and programming can require technical proficiency. Maintenance and troubleshooting may be challenging, particularly for diagnosing and rectifying issues. Cost is an essential consideration, as high-quality motion controllers and supplementary components come with an associated investment. Compatibility challenges can arise, demanding hardware and software integration. It's essential to consider these factors to ensure successful implementation of motion controllers in your industrial motion control solution.

Fundamentals of Motion Controllers

Motion controllers are essential devices when it comes to controlling the movements of mechanical systems. Understanding the fundamentals of motion controllers is crucial for anyone involved in the field of automation and industrial motion control.

At the core of motion controllers is their command and control logic. This logic enables them to comprehend, interpret, and execute specific movement instructions with precision and accuracy. These instructions can be given in various input formats, ranging from high-level programming languages to simpler point-and-click interfaces.

Processing power is another key aspect of motion controllers. With different levels of processing power, controllers can handle complex movement patterns and calculations, ensuring smooth and efficient control over the mechanical system.

Once the commands are processed, motion controllers generate output signals in the form of electrical signals that are sent to motion devices. These signals initiate the desired movement, bringing the mechanical system to life.

Feedback systems play a critical role in maintaining the accuracy and reliability of motion controllers. Encoders and resolvers are commonly used as feedback devices, providing real-time feedback on position, speed, and torque.

The drive interface is an essential component of motion controllers. It converts the commands received from the controller into physical motion. Different drive types and signal transmission methods are utilized to ensure seamless communication between the controller and the motion devices.

Motion controllers are capable of governing various types of motion, including point-to-point motion, continuous motion, and synchronized motion. This versatility allows them to meet the specific requirements of different applications and industries.

Understanding the fundamentals of motion controllers provides a strong foundation for utilizing these devices effectively in industrial automation and motion control applications. By harnessing their command and control logic, input formats, processing power, output signals, feedback systems, drive interface, and various types of motion, motion controllers enable precise and efficient control over mechanical systems.

Advantages of Motion Controllers

Motion controllers offer a range of advantages in the world of automation. Their capabilities and features make them indispensable for industries that rely on precision, efficiency, and safety in their operations.

Precision and Accuracy

Motion controllers enable precise and accurate movements in automated systems. Through real-time adjustments, they ensure that the system follows the desired path or reaches a specific position with utmost accuracy. This level of precision is crucial for industries that require tight tolerances and exact positioning, such as manufacturing and robotics.

Elimination of Manual Errors

By relying on pre-programmed instructions and real-time feedback, motion controllers eliminate the risk of manual errors. Human errors can lead to costly mistakes and safety hazards in complex operations. By automating these sequences, motion controllers ensure consistent and error-free performance, enhancing overall productivity.

Speed and Efficiency

Motion controllers significantly improve the speed and efficiency of systems. By automating complex sequences of movements, they reduce downtime caused by errors and optimize production cycles. The ability to precisely control acceleration and deceleration also enhances the efficiency of movements, resulting in faster and more streamlined operations.

Versatility

Motion controllers are highly versatile and can adapt to different types of motion. Whether it's point-to-point motion, continuous motion, or synchronized motion, these controllers can handle a wide range of applications in various industries. This versatility makes them suitable for use in diverse automated systems and processes.

Safety

Safety is a top priority in any industrial setting. Motion controllers contribute to safety by continuously monitoring operational parameters and initiating corrective actions when necessary. They can detect anomalies, such as sudden changes in position or unexpected forces, and trigger immediate responses to prevent accidents or system failures.

Integration

Integration is a key feature of motion controllers that allows them to work seamlessly with other system components. These controllers can be easily integrated into existing systems, providing centralized control and enhancing overall system functionality. The ability to integrate with other devices and technologies further expands the capabilities and possibilities of automated systems.

With their precision, elimination of manual errors, speed, versatility, safety features, and integration capabilities, motion controllers have become indispensable in modern automation. Their benefits go far beyond improved efficiency and accuracy, transforming industries and revolutionizing the way tasks are performed.

Challenges and Considerations

While motion controllers offer significant advantages, there are also challenges and considerations to keep in mind when adopting them. One of the primary challenges is the complexity involved in setting up and programming advanced motion controllers. This process often requires deep technical knowledge and expertise to ensure optimal performance.

Maintenance and troubleshooting can also pose challenges. Diagnosing and rectifying issues with motion controllers typically require specialized skills and experience. Regular maintenance, including software updates and periodic check-ups, is essential to ensure the controllers' longevity and optimal functionality.

The cost is another important consideration when implementing motion controllers. High-end motion controllers and accompanying components can come with a substantial price tag. It's crucial to carefully evaluate the return on investment and consider long-term expenses, such as software updates and ongoing maintenance.

Additionally, compatibility challenges may arise, especially when integrating motion controllers into mixed-brand or older systems. Hardware and software integration may be necessary, requiring careful planning and collaboration with experts to ensure seamless compatibility.

FAQ

A motion controller is a device designed to control the sequence, velocity, position, and torque of a mechanical system.

Motion controllers are used in various industries, including manufacturing, medicine, entertainment, and research.

Motion controllers interpret desired movements or actions and convert them into electrical signals to drive motion components.

The main advantages of motion controllers are precision and accuracy, real-time adjustments, elimination of manual errors, speed and efficiency, versatility, safety, and integration.

Challenges and considerations with motion controller adoption include complexity, cost, and compatibility.

Motion controllers have command and control logic, input formats, processing power, output signals, feedback systems, drive interfaces, and can govern different types of motion.

Motion controllers enable precision and accuracy, eliminate manual errors, improve speed and efficiency, enhance safety, and offer integration capabilities.

Maintenance and troubleshooting can be challenging and may require technical expertise in diagnosing and rectifying issues.

High-end motion controllers and supplementary components can come with a substantial price tag, and ongoing expenses such as software updates and maintenance should be considered.

Compatibility challenges can arise, especially in mixed-brand or older systems, where hardware and software integration may be required.