| How
to Build a Radio on a Chip (word,
pdf)
I study design techniques that will allow
people to build inexpensive miniature radios
with a single silicon chip and a couple of
other small components. I also study ways
of reducing the power consumption of such
radios so that they may be used in portable
devices that require a long battery life.
I expect that this work will lead to new applications
where miniature, low-cost radios will be incorporated
into everyday devices and appliances. This
will enable new, useful applications in areas
such as ambulatory health monitoring, building
& environmental monitoring, inventory management,
wireless Internet access, and home and factory
automation. I hope that the impact of small,
inexpensive single-chip radios will be no
less than that of the microprocessor revolution,
which made microprocessor-controlled devices
so pervasive in today's world.
Some are called smart tags,
others Radios-on-a-Chip (ROCs), some other
go by code names such as IEEE-802.11 or Bluetooth.
These wireless devices allow communication
between all computers, handheld devices and
peripherals. They give us the freedom to roam
about the building with our laptops, personal
digital assistants (PDAs), pagers, etc. But
what are these wireless devices, and why should
we care about them?
With current silicon technology
it is possible to fit all the major components
of a radio transmitter and receiver in a millimeter
square of area, i.e., no larger than the head
of a pin. A chip radio of this size will cost
about 10 cents to manufacture. The small cost
of this device opens up possibilities for
use in applications not possible before because
they were too expensive. The main problem
is that in a typical radio receiver, a significant
amount of power is used by what is called
the local oscillator (LO). The LO generates
a high frequency signal used to detect the
signal we are interested in receiving. To
receive different channels, we need to control
very precisely the frequency of the LO. This
is usually done using a frequency synthesizer.
The frequency synthesizer is also an important
component of a radio transmitter.
A frequency synthesizer is composed
of an oscillator (LO), frequency divider,
and a phase detector. In essence, the oscillator's
frequency tracks the frequency of a quartz
crystal, but at a multiple of the frequency
divider ratio. So, for example, if the crystal
is oscillating at 10 MHz and the divider is
set to divide by 100, the oscillator frequency
becomes 1000 MHz.
My main research goal is to
develop techniques that will allow the design
and construction of a very small radio receiver
that fits on a single 1-mm squared silicon
chip and will be suitable for low-cost applications.
To accomplish this goal, we must be able to
integrate all the components of a frequency
synthesizer suitable for a radio into a single
chip. This task is a challenge. Also, the
synthesizer uses a significant amount of power.
Minimizing the power required by the synthesizer
will have a great impact in reducing the power
used by the whole radio receiver, thus significantly
increasing the battery life. For these reasons,
we are studying how to minimize the power
usage of the synthesizer with a special emphasis
in the oscillator and frequency dividers.
A ring oscillator is very small
and easy to integrate into a chip. We studied
the properties of different kinds of ring
oscillators and their suitability for use
in a frequency synthesizer. We also studied
how to use ring oscillators as frequency dividers.
Conventional frequency dividers use more power
as their division ratio increases, i.e., dividing
the frequency by 8 requires more power than
dividing it by 4. We are studying a technique
that has the opposite behavior, i.e., division
by 8 uses less power than division by 4. This
technique called injection locking promises
power savings of up to a factor of ten in
the frequency divider alone.
Applications that will benefit
the most from this technology require the
radios to be within 10 meters while using
the 900-MHz frequency band commonly used in
cordless phones. Many applications also need
the radio to operate for hundreds of hours
using only a small battery. For instance,
a pacemaker could communicate with a PDA and
send an alarm to the hospital over the Internet.
We could also monitor the health condition
of a baby in-utero. A smart sensor could be
embedded into a building constantly monitoring
the stress in the structure. Disposable merchandise
tags could be interrogated wirelessly in a
store allowing instant inventory counts. The
applications are virtually endless. |
Most
biotelemetry applications deal with the moderated
data rates of biological signals. Few people
have studied the problem of transcutaneous
data transmission at the rates required by
NASA's Life Sciences-Advanced BioTelemetry
System (LS-ABTS). Implanted telemetry eliminate
the problems associated with wire breaking
the skin, and permits experiments with awake
and unrestrained subjects. Our goal is to
build a low-power 174-216MHz RF transmitter
suitable for short range biosensor and implantable
use.