Honeywell Optical Encoders 1

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Manufacturers (1)
    • Honeywell
    • Agilent Technologies
    • Alps Alpine
    • Alps Electric
    • Analog Devices
    • Baumer Electric Ag
    • Bourns
    • Broadcom
    • Cts
    • Cui
    • Elma Electronic
    • Grayhill
    • Hans Turck & KG
    • Hewlett Packard
    • Honeywell Sensing And Control
    • Infineon Technologies
    • Nidec Copal Electronics
    • Omron
    • Sharp Corporation
    • Texas Instruments
    • Tt Electronics Plc
    • Us Digital
    • Wurth Elektronik
Optoelectronic Type
    • ABSOLUE ROTARY ENCODER
    • INCREMENTAL ROTARY ENCODER
    • LINEAR POSITION ENCODER
    • ROTARY POSITION ENCODER
    • ROTARY/LINEAR POSITION ENCODER
Mounting Feature
    • BOARD MOUNT
    • CHASIS MOUNT
    • CHASSIS MOUNT
    • PANEL MOUNT
    • SURFACE MOUNT
    • THROUGH HOLE MOUNT
Terminal Finish
    • GOLD
    • GOLD OVER NICKEL
    • Gold (Au)
    • Gold (Au) - with Nickel (Ni) barrier
    • Matte Tin (Sn)
    • Matte Tin (Sn) - annealed
    • NICKEL
    • NICKEL PALLADIUM GOLD
    • Nickel (Ni)
    • Nickel/Gold (Ni/Au)
    • Nickel/Palladium/Gold (Ni/Pd/Au)
    • SILVER
    • TIN
    • TIN LEAD
    • TIN SILVER COPPER
    • Tin (Sn)
    • Tin/Lead (Sn/Pb)
Maximum On State Voltage
    • 18 V
Configuration
    • DUAL, 2 CHANNELS
    • SINGLE
    • SINGLE, 13 CHANNELS
    • SINGLE, 2 CHANNELS
    • SINGLE, 3 CHANNELS
    • SINGLE, 6 CHANNELS
    • SINGLE, 8 CHANNELS
Maximum Supply Voltage
    • 12 V
    • 24 V
    • 250 V
    • 3.5 V
    • 3.6 V
    • 3.63 V
    • 30 V
    • 5 V
    • 5.2 V
    • 5.25 V
    • 5.5 V
    • 7 V
No. of Functions
    • 1
No. of Elements
    • 2
Peak Wavelength (nm)
    • 630
Packing Method
    • TR
    • TR, 7 INCH
    • TRAY
Output Circuit Type
    • Amplifier
    • Photodiode
    • Schmitt Trigger
Maximum Response Time
    • .0000001 s
    • .00000018 s
    • .0000002 s
    • .0000003 s
Sub-Category
    • Optical Position Encoders
    • Other Optoelectronics
Maximum Operating Temperature
    • 100 Cel
    • 105 Cel
    • 115 Cel
    • 125 Cel
    • 140 Cel
    • 45 Cel
    • 50 Cel
    • 55 Cel
    • 60 Cel
    • 65 Cel
    • 70 Cel
    • 75 Cel
    • 80 Cel
    • 85 Cel
    • 90 Cel
Minimum Operating Temperature
    • -10 Cel
    • -20 Cel
    • -25 Cel
    • -30 Cel
    • -40 Cel
    • -5 Cel
    • -60 Cel
    • -65 Cel
    • 0 Cel
    • 15 Cel
Additional Features
    • CAN ALSO OPERATE ON 5.5V
    • CAN ALSO OPERATE ON 5V, TTL COMPATIBLE
    • CMOS AND TTL COMPATIBLE
    • Can also operate on 5.5V
    • HIGH RELIABILITY
    • TTL COMPATIBLE
    • UL APPROVED
JESD-609 Code
    • e0
    • e1
    • e3
    • e4
Gap Size
    • 1.7 mm
    • 1.78 mm
    • 3.2 mm
Maximum On State Current
    • .005 A
    • .016 A
Reset All
Part RoHS Manufacturer Optoelectronic Type Mounting Feature Terminal Finish Maximum On State Voltage Configuration Maximum Supply Voltage No. of Functions No. of Elements Peak Wavelength (nm) Packing Method Output Circuit Type Maximum Response Time Sub-Category Maximum Operating Temperature Minimum Operating Temperature Additional Features JESD-609 Code Gap Size Maximum On State Current

600EN-128CBL

Honeywell

ROTARY POSITION ENCODER

SINGLE, 2 CHANNELS

1

65 Cel

-40 Cel

Optical Encoders

Optical encoders are electronic devices that convert rotary or linear motion into digital signals. They are commonly used in a wide range of applications, including industrial automation, robotics, and computer peripherals.

Optical encoders consist of a light source, a sensing element, and a rotating or linear scale. The light source, typically an LED or laser, emits light onto the scale, and the sensing element, typically a photodiode or phototransistor, detects the light reflected back from the scale. The sensing element generates a signal based on the amount of light detected, which is then processed by an electronic circuit to produce a digital output signal.

Optical encoders can be categorized into two types based on their operating principle: incremental and absolute. Incremental encoders generate a series of digital pulses that correspond to the relative position of the encoder, while absolute encoders generate a unique digital code that corresponds to the absolute position of the encoder.