Inside a
Mouse
The main goal of any mouse is to
translate the motion of your hand into
signals that the computer can use.
Almost all mice today do the translation
using five components:
The guts of a
mouse
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A ball inside the mouse
touches the desktop and rolls when
the mouse moves.
The
underside of the mouse's
logic board: The exposed
portion of the ball touches
the desktop.
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Two rollers inside the
mouse touch the ball. One of the
rollers is oriented so that it
detects motion in the X direction,
and the other is oriented 90 degrees
to the first roller so it detects
motion in the Y direction. When the
ball rotates, one or both of these
rollers rotate as well. The
following image shows the two white
rollers on this mouse:
The
rollers that touch the ball
and detect X and Y motion
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The rollers each connect to a
shaft, and the shaft spins a
disk with holes in it. When a
roller rolls, its shaft and disk
spin. The following image shows the
disk:
A typical
optical encoding disk: This
disk has 36 holes around its
outer edge.
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On either side of the disk there
is an infrared LED and an
infrared sensor. The holes in
the disk break the beam of
light coming from the LED so
that the infrared sensor sees pulses
of light. The rate of the pulsing is
directly related to the speed of the
mouse and the distance it travels.
A
close-up of one of the
optical encoders that track
mouse motion: There is an
infrared LED (clear) on one
side of the disk and an
infrared sensor (red) on the
other.
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An on-board processor chip
reads the pulses from the infrared
sensors and turns them into binary
data that the computer can
understand. The chip sends the
binary data to the computer through
the mouse's cord.
The logic
section of a mouse is dominated
by an encoder chip, a small
processor that reads the pulses
coming from the infrared sensors
and turns them into bytes sent
to the computer. You can also
see the two buttons that detect
clicks (on either side of the
wire connector).
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In this optomechanical
arrangement, the disk moves
mechanically, and an optical system
counts pulses of light. On this mouse,
the ball is 21 mm in diameter. The
roller is 7 mm in diameter. The encoding
disk has 36 holes. So if the mouse moves
25.4 mm (1 inch), the encoder chip
detects 41 pulses of light.
You might have noticed that each
encoder disk has two infrared LEDs and
two infrared sensors, one on each side
of the disk (so there are four
LED/sensor pairs inside a mouse). This
arrangement allows the processor to
detect the disk's direction of
rotation. There is a piece of
plastic with a small, precisely located
hole that sits between the encoder disk
and each infrared sensor. It is visible
in this photo:
A close-up of
one of the optical encoders that
track mouse motion: Note the
piece of plastic between the
infrared sensor (red) and the
encoding disk.
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This piece of plastic provides a
window through which the infrared sensor
can "see." The window on one side of the
disk is located slightly higher than it
is on the other -- one-half the height
of one of the holes in the encoder disk,
to be exact. That difference causes the
two infrared sensors to see pulses of
light at slightly different times. There
are times when one of the sensors will
see a pulse of light when the other does
not, and vice versa.
This page offers a nice explanation
of how direction is determined.
The
Optical Mouse
With advances it mouse technology, it
appears that the venerable wheeled mouse
is in danger of extinction. The
now-preferred device for pointing and
clicking is the optical mouse.
This
Microsoft Intellimouse uses
optical technology.
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Developed by Agilent Technologies and
introduced to the world in late 1999,
the optical mouse actually uses a tiny
camera to take 1,500 pictures
every second.
Able to work on almost any surface,
the mouse has a small, red
light-emitting diode (LED) that
bounces light off that surface onto a
complimentary metal-oxide semiconductor
(CMOS) sensor. The CMOS sensor sends
each image to a digital signal
processor (DSP) for analysis. The
DSP, operating at 18 MIPS (million
instructions per second), is able to
detect patterns in the images and see
how those patterns have moved since the
previous image. Based on the change in
patterns over a sequence of images, the
DSP determines how far the mouse has
moved and sends the corresponding
coordinates to the computer. The
computer moves the cursor on the
screen based on the coordinates
received from the mouse. This happens
hundreds of times each second, making
the cursor appear to move very smoothly.
In this
photo, you can see the LED on
the bottom of the mouse.
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Optical mice have several benefits
over wheeled mice:
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No moving parts means less wear
and a lower chance of failure.
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There's no way for dirt to get
inside the mouse and interfere with
the tracking sensors.
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Increased tracking resolution
means smoother response.
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They don't require a special
surface, such as a mouse pad.
Apple has
transformed its optical mouse
into a modern work of art.
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Although LED-based optical mice are
fairly recent, another type of optical
mouse has been around for over a decade.
The original optical-mouse technology
bounced a focused beam of light off a
highly-reflective mouse pad onto a
sensor. The mouse pad had a grid of dark
lines. Each time the mouse was moved,
the beam of light was interrupted by the
grid. Whenever the light was
interrupted, the sensor sent a signal to
the computer and the cursor moved a
corresponding amount.
This kind of optical mouse was
difficult to use, requiring that you
hold it at precisely the right angle to
ensure that the light beam and sensor
aligned. Also, damage to or loss of the
mouse pad rendered the mouse useless
until a replacement pad was purchased.
Today's LED-based optical mice are far
more user-friendly and reliable.
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