Indicator Descriptions

INDICATOR DEFINITION

OPERATION

PROGRAMMING

INDICATION WHEN LIT

DURING NORMAL OPERATION

INDICATION WHEN LIT

DURING PROGRAMMING

24 VOLT INPUT

 

LOW VOLTAGE AC POWER IS PRESENT

 

POWER

 

 

 

 

 

 

 

 

 

24 VOLT DC

 

LOW VOLTAGE DC POWER IS PRESENT

 

ACCY POWER

 

 

 

 

 

 

 

 

 

 

 

OPEN SIGNAL PRESENT FROM THE INTERNAL

 

OPEN

 

RECEIVER OR AN EXTERNAL DEVICE

 

 

 

CONNECTED TO THE OPEN INPUT TERMINAL

 

 

 

 

 

CLOSE

 

CLOSE SIGNAL IS PRESENT FROM A DEVICE

 

 

CONNECTED TO THE CLOSE INPUT TERMINAL

 

 

 

 

 

 

 

 

STOP

 

STOP INPUT TERMINAL IS OPEN AND

 

 

NOT CONNECTED TO COMMON

 

 

 

 

 

 

 

 

PROGRAM

 

 

CONTROLLER IS IN PROGRAMMING MODE

 

 

 

 

REVERSE

DELAY SET

SIGNAL FROM REVERSING DEVICE IS PRESENT

SET REVERSE DELAY TIME

 

 

 

 

LOCKOUT

ALARM SET

CONTROLS AND OPERATOR ARE LOCKED OUT

SET RUN ALARM AND PRE-START ALARM

BECAUSE OF EXISTING TROUBLE CONDITION

 

 

 

 

 

 

 

RADIO

LEARN

BUILT-IN RECEIVER IS DETECTING A RADIO

TRANSMITTERS CAN BE ENTERED INTO

SIGNAL FROM A REMOTE CONTROL

MEMORY (UP TO 40 TRANSMITTERS)

 

 

 

 

 

 

OPEN CURRENT

SET

MOTOR CURRENT HAS EXCEEDED THE

SET MAXIMUM OPEN CURRENT

OPEN CURRENT SETTING WHILE OPENING

 

 

 

 

 

 

 

 

 

OPEN OBSTRUCTION TERMINAL CONNECTED

 

OPEN OBSTR

MGT 2 SET

TO COMMON BY BEAM OR SAFETY EDGE, OR

SET MGT #2 FUNCTION

 

 

SIGNAL FROM MGT OBSTACLE TRANSMITTER

 

 

 

 

 

OPEN RELAY

LH/RH SET

OPEN RELAY IS ACTIVATED

SET LEFT-HAND RIGHT-HAND OPERATION

 

 

 

 

OPEN LIMIT

BRAKE DELAY

OPEN LIMIT SWITCH IS ACTIVATED

 

 

 

 

 

CLOSE CURRENT

SET

MOTOR CURRENT HAS EXCEEDED THE

SET MAXIMUM CLOSE CURRENT

CLOSE CURRENT SETTING WHILE CLOSING

 

 

 

 

 

 

 

 

 

CLOSE OBSTRUCTION TERMINAL CONNECTED

 

CLOSE OBSTR

MGT 1 SET

TO COMMON BY BEAM OR SAFETY EDGE, OR

SET MGT #1 FUNCTION

 

 

SIGNAL FROM MGT OBSTACLE TRANSMITTER

 

 

 

 

 

CLOSE RELAY

AUTO CLOSE SET

CLOSE RELAY IS ACTIVATED

SET AUTO-CLOSE TIME

 

 

 

 

CLOSE LIMIT

AC DC SET

CLOSE LIMIT SWITCH IS ACTIVATED

SET MOTOR TYPE

 

 

 

 

SINGLE

SET

SINGLE TERMINAL CONNECTED TO COMMON

SET SINGLE BUTTON INPUT FUNCTION

BY AN EXTERNAL PUSHBUTTON OR RADIO

 

 

 

 

 

 

 

MAX RUN

SET

MAXIMUM RUN TIMER HAS BEEN EXCEEDED

SET MAXIMUM RUN TIME

 

 

 

 

COMM LINK

SET

DUAL OPERATOR CONNECTION DETECTED,

 

BLINKS IF CONNECTION HAS FAILED

 

 

 

 

 

 

 

 

MAINT ALERT

SET

MAINTENANCE IS REQUIRED ON OPERATOR

SET MAINTENANCE ALERT CYCLE COUNT

 

 

 

 

"RL"

LEFT OR RIGHT HAND OPERATION

APEX FUNCTION DISPLAY INDICATIONS

"MO"

MOTOR TYPE SELECTION

"PM"

"AC"

SINGLE OR DUAL GATE

AUTO CLOSE TIMER

"RT"

"SB"

MAXIMUM

RUN TIMER

SINGLE BUTTON INPUT SETUP

LOW POWER

"LP" MODE

POWER

"FS" FAILURE MODE

"RA"

"TL"

RADIO

ENABLE

LEARN

TRANSMITTERS

"RP"

"OC"

"CC"

"AD"

RUN ALARM

PRE-START ALARM

MAXIMUM OPEN CURRENT

MAXIMUM CLOSE CURRENT

ADVANCED

PROGRAMMING

"SM"

"ST"

"AR"

"RD"

STAGGER

MODE

STAGGER

TIME

AUXILIARY

RELAY MODE

REVERSE DELAY TIME

"SS"

"CT"

"MA"

"MT"

SOFT START/STOP DURATION

RESET CYCLE

COUNT

MAINTENANCE ALERT TRIGGER

MID-TRAVEL

STOP POSITION

"TD"

"ML"

"MD"

"CL"

DELETE

TRANSMITTERS

LEARN MGT

TRANSMITTERS

ERASE MGT

TRANSMITTERS

RESET TO

FACTORY DEFAULTS

SWR SWC SWD Swing Gate Operator Installation Guide

- 9 -

227965 Revision X13 3-28-2008

Page 11
Image 11
Linear SWC, SWR, SWD manual Indicator Descriptions

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.