Linear SWD, SWR Photoeye Installation Illustration, Refer to Connection Illustrations for Details

Page 22

SWR SWC SWD Swing Gate Operator Installation Guide - 20 -

227965 Revision X13 3-28-2008

OBSTRUCTION DETECTING APPLICATION

(WIRE TO CLOSE OBSTRUCTION)

BEAM PATH

THIS DRAWING IS INTENDED TO DRAW ATTENTION TO POSSIBLE LOCATIONS FOR THE INSTALLATION OF CONTACT OR NON-CONTACT OBSTRUCTION SENSING DEVICES. OTHER AREAS OF ENTRAPMENT MAY EXIST DEPENDING ON EACH SPECIFIC INSTALLATION.

CARE MUST BE TAKEN TO POSITION PHOTOEYES SO THAT NUISANCE TRIPPING IS MINIMIZED.

SEPARATE PEDESTRIAN GATE REQUIRED

7 FT. MINIMUM DISTANCE AWAY FROM GATE

PHOTOEYE REVERSE APPLICATION

(WIRE TO REVERSE)

BEAM PATH

BEAM PATH

OBSTRUCTION DETECTING APPLICATION (WIRE TO OPEN OBSTRUCTION)

REFER TO CONNECTION ILLUSTRATIONS FOR DETAILS

Photoeye Installation Illustration

Image 22
Contents SWR SWC SWD Table of Contents Regulatory Warnings Before You BeginAlways Check the Gate’s Action Gate Operator ClassificationsAC Power Wiring Wiring SpecificationsDC Control and Accessory Wiring Mounting Pad Installation Mounting Pad SpecificationsSetting Left or Right Hand Configuration Gate Arm InstallationVent Plug Installation Gate Plate InstallationChoosing Good Harmonics Installing the Gate Arm on the OperatorSetting the Arm Lengths Good BAD HarmonicsAC Power Connection Operator SetupController Access Connect AC Power Pigtail Leads to AC SourceLimit Cam Fine Adjustment Limit Cam Rough AdjustmentTorque Limiter Adjustment CamsDisplay Controller FeaturesButtons Indicator Descriptions Terminal Descriptions Operator Accessory Connections Operator Accessory ConnectionsBasic Controller Programming Maximum Close Direction Current Setting Run Alarm and Pre-start AlarmMaximum Open Direction Current Setting RUN Alarm PRE-START AlarmAdvanced Controller Programming Low Power Mode Auxiliary Relay ModeReverse Delay Time Power Failure ModeSoft Start/Stop Duration Reset Cycle CountMaintenance Alert Trigger Mid-travel Stop PositionReset Controller to Factory Defaults Radio EnableAntenna Installation Radio Transmitter LearnUSE Relief Cuts AT Corners Loop Layout IllustrationLoop Safety Edge Layout Illustration Retaining BracketPhotoeye Installation Illustration Refer to Connection Illustrations for DetailsDual Gate Installations Gate OperationError Indications Operation IndicationsTroubleshooting Model SWR Exploded View DescriptionModel SWC Exploded View Model SWD Exploded View SWR, SWC, SWD Gate Arm Assembly Exploded View DC Motor Brush Replacement Model SWD MaintenanceBattery Maintenance When NEWFCC Notice Preventative MaintenanceMonth Preventative Maintenance GeneralGate Operator Installation Checklist

SWR, SWD, SWC specifications

Linear SWC (Single Wire Control), SWD (Single Wire Debug), and SWR (Single Wire Radio) are advanced communication protocols widely utilized in embedded systems and electronic applications. These protocols enhance the efficiency of data transmission, reduce the number of physical connections required, and simplify the design process for developers.

The main feature of Linear SWC is its ability to transmit control signals over a single wire, allowing for straightforward connectivity between microcontrollers and various peripherals. This approach minimizes the complexity of printed circuit boards (PCBs) and reduces the space needed for connections, making it ideal for compact designs. Linear SWC operates based on a master/slave architecture, where the master device initiates communication, and the slave devices respond.

SWD, primarily used for debugging embedded systems, is a two-pin interface that supports high-speed data transfer with minimal pin usage. Unlike traditional JTAG, SWD is simpler and more efficient, allowing developers to perform debugging and programming tasks with fewer resources. The SWD protocol offers features such as breakpoint management, memory read/write capabilities, and real-time variable monitoring, empowering developers to optimize their code and increase debugging efficiency.

SWR is focused on wireless communication, leveraging a single wire for transmitting radio signals. This technology is particularly advantageous in applications requiring minimal hardware while maintaining robust connectivity. SWR supports various modulation techniques and can operate in different frequency bands, making it versatile for various use cases. The single-wire approach reduces the complexity of antenna design and enhances the overall reliability of wireless communications in challenging environments.

One of the key characteristics shared by SWC, SWD, and SWR is their ability to reduce power consumption. By minimizing the number of connections and optimizing signal paths, these protocols significantly decrease the energy required for data transmission. Additionally, their compatibility with a wide range of microcontrollers and integrated circuits contributes to their widespread adoption in modern electronic designs.

In summary, Linear SWC, SWD, and SWR serve critical roles in the evolution of embedded systems, offering unique features, advanced technologies, and efficient characteristics. Their capability to simplify designs, reduce power consumption, and enhance overall communication quality makes them essential tools for engineers and developers in today's fast-paced technological landscape. As the demand for compact, efficient solutions grows, these protocols are poised to play an increasingly significant role in future innovations.