THROUGH HOLE MOUNT Optical Encoders 22
| 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 |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Us Digital |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
2 |
.0000002 s |
Other Optoelectronics |
100 Cel |
-40 Cel |
1.78 mm |
.005 A |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 2 CHANNELS |
1 |
70 Cel |
-10 Cel |
HIGH RELIABILITY |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Bourns |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
TIN |
SINGLE, 2 CHANNELS |
5 V |
1 |
75 Cel |
-40 Cel |
e3 |
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|
|
Broadcom |
ROTARY POSITION ENCODER |
THROUGH HOLE MOUNT |
SINGLE, 3 CHANNELS |
5.5 V |
1 |
Optical Position Encoders |
85 Cel |
-40 Cel |
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.