Implantable ultralow-power radio chip facilitates in

Semiconductor Technology
Implantable ultralow-power radio chip
facilitates in-body communications
Targeting implantable applications like pacemakers, nerve stimulators, drug
pumps, and other such medical devices, an ultralow-power RF transceiver
chip has been developed that delivers high data rates, low power consumption
and unique wake-up circuitry. This article discusses the design of an in-body
communication system.
By Peter D. Bradley
T
he development of integrated circuits
(ICs) and medical devices has evolved
in concert over the past 30 years.
Circuit technology has facilitated the evolution
of increasingly complex, highly integrated
and smaller medical devices. At the same
time, burgeoning healthcare costs combined
with a more affluent, more obese and longerliving population, has created demand for
new applications and therapies relying on
implanted medical devices that are wirelessly
linked to base stations.
Brief history
Traditionally, communication systems in
implanted medical devices have used very
short-range magnetic coupling. This required
close coupling between the programmer and
medical device and often delivered data rates
of less than 50 kbps.
To overcome the range limitations, the
402 MHz to 405 MHz medical implant
communication service (MICS) band was
established in 1999, with similar standards
following in Europe[1,2]. This band supports
the use of longer range (typically two meters),
relatively high-speed wireless links. The
402 MHz to 405 MHz band is well suited for
this service, due to the signal propagation
characteristics in the human body, compatibility with the incumbent users of the band (meteorological aids such as weather balloons),
and its international availability (Figure 1).
Electronic systems for implanted medical
applications present formidable low-power
design challenges. For example, most implanted pacemakers have lifetime requirements
of greater than seven years with maximum
current drains on the order of 10 µA to 20 µA.
The communication systems are budgeted at
total currents averaged over the device lifetime
of no more than about 15% of the total power
budget or 2 µA to 3 µA due to the current
consumption demands of supporting pacing
therapy. Receivers in implanted medical
systems must periodically “sniff” or monitor
for an external communication device, and
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706RFDF1.indd 20
conserve power by remaining off in a very
low power state when not sniffing.
Design considerations
To enable the use of the MICS band,
implanted medical devices require an
ultralow-power, high-performance transceiver. Implanted device transceiver design
faced numerous challenges:
 Low power during 400 MHz communications. Implant battery power is limited and
the impedance of implant batteries is relatively
high. This limits peak currents that may be
drained from the supply.
 During communication sessions, current
should be limited to less than 6 mA for most
implantable devices.
 Low power when asleep and periodically
“sniffing” for a wake-up signal.
 Minimum external component count
and physical size. Implant-grade components
are expensive and high levels of integration
may reduce costs and increase overall system
reliability.
 Reasonable data rates. Pacemaker
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applications are currently demanding
>20 kbps, with much higher data rates projected for the future.
 High system and data transmission
reliability.
 Selectivity and interferer rejection
especially from TETRA radios in Europe.
 Typically greater than two-meter range.
Longer ranges imply good sensitivity is needed
since small antennas and body loss affect link
budget and allowable range. Antenna, matching, fading and body losses are quite variable
with losses as high as 40 dB to 45 dB.
The ZL70101 MICS transceiver offers
exceptionally low power consumption while
providing a high data rate. The transmit
and receive current is less than 5 mA when
operating at a data rate of up to 800 kbps.
The circuit features a unique ultralow-power
wakeup system operating at 2.45 GHz that
enables an average sleep/sniffing current of
less than 250 nA. System integration is high
and only three external components (crystal
and two decoupling capacitors) and a matching
network are required.
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6/21/2007 3:58:07 PM
Medical devices may be categorized into
those that use an internal non-rechargeable
battery (e.g., pacemakers) and those that
couple power inductively (e.g., cochlea
implants). The former heavily duty-cycle the
operation of systems to conserve power. The
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Figure 1. Benefits of MICS band.
transceiver is off most of the time, therefore,
the off-state current and the current required
to periodically look for a communicating
device must be extremely low (<1-2 µA). In
both cases, low power (<6 mA) for transmit
and receive is also required.
The ZL70101 has
a peak Rx/Tx current
consumption of <5 mA
operating from a supply voltage of between
2.1 V to 3.5 V. This
current includes the
basic RF transceiver
and MAC current. The
MAC ensures the user
receives high integrity
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data and automatically
performs much of the
required link maintenance. Furthermore, the
MAC protocol offers a
power-save timer that
turns off the receiver in
the implant for a programmable time after
transmitting a packet.
For minimum over���������
all power consumption, defined in terms of
Joules/bit, it is recom-
Modulation Mode
Data Rate (kbps)
Receiver Sensitivity
(µVrms)
Receiver Sensitivity
(dBm)
2 FSK
200
<14
-99
2 FSK
400
<25
-94
4 FSK
800
<80
-84
Note: The effective impedance at the Rx input is higher (~1600 Ω).
Table 1. Data rate vs. receiver sensitivity.
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Figure 2. Overall system architecture with the ZL70101 MICS transceiver operating in the implanted
medical device and base station.
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706RFDF1.indd 22
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mended that implantable transceivers should
use the highest possible data rate that satisfies
the application receiver sensitivity requirements. Systems that require low data rates
(even in the low kHz range) should buffer
data, operate at the highest data rate possible
and exploit duty cycling to reduce the average
current consumption. Sending data in short
bursts conserves power and reduces the time
window allowed for interference. In addition,
in systems with high battery impedance the
power supply decoupling requirements may be
more forgiving due to shorter bursts of charge
drawn from capacitors.
The transceiver allows the user to select
from a wide range of data rates (200 kbps,
400 kbps, 800 kbps) with varying receiver
sensitivity. To facilitate this flexibility, the
system uses either 2 FSK or 4 FSK modulation with 200 or 400 ksymbols per second
and varying frequency deviations (Table 1).
Lower data rates and correspondingly higher
receiver sensitivity may be attained by off-chip
digital filtering. The transceiver has a MAC
bypass mode of operation in which the radio
is fully accessible. In this configuration, the
user may develop customized protocols and
data rates.
Overall system architecture
The ZL70101 operates in the implanted
device and external base station (Figure 2).
The base station includes additional circuitry
to transmit a 2.45 GHz wake-up signal. Once
the system is started via the 2.45 GHz wake-up
signal, data is exchanged using the 402 MHz
to 405 MHz MICS band transceiver.
The ZL70101 MICS chip (Figure 3) consists of three main subsystems: a 400 MHz
transceiver, a 2.45 GHz wake-up receiver
and a media access controller (MAC). The
chip may be used as the transceiver in either
an implanted medical device or a base station
programmer as determined by the state of
an input pin.
The transceiver uses a low intermediate
frequency (IF) superheterodyne architecture
with image reject mixers. The low-IF minimizes filter and modulator power consumption
without the flicker noise and dc offset problems associated with high data rate, zero-IF
architectures. An FSK modulation scheme
reduces Tx amplifier linearity requirements,
thereby reducing power consumption and
allowing for a simpler limiting receiver.
The 400 MHz transmitter subsystem,
labeled half-duplex RF transmitter shown in
Figure 3, consists of an IF modulator, mixer
and power amplifier. The IF modulator converts a one-bit (2 FSK) or two-bit (4 FSK)
asynchronous digital input data stream to
an intermediate frequency. An upconverting
mixer transforms the IF to RF frequency.
Note that the local oscillator frequency is the
June 2007
6/21/2007 3:58:09 PM
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Figure 3. Block diagram of ZL70101 MICS transceiver showing the three main subsystems: a
400 MHz transceiver, a 2.45 GHz wake-up receiver and a media access controller (MAC).
Parameter
Specification
Technology
0.18 um RF CMOS
Supply voltage
2.1 V – 3.5 V
Radio frequency
402 MHz – 405 MHz
(10 ch. MICS), 432 – 434 (2 ch. ISM)
Max. raw data rate
800 kbps
400 MHz sensitivity at 200 kbps
–99 dBm
Current (Tx/Rx)
5 mA
Current (sleep + sniffing)
250 nA
Estimated range
>2 meters
Final BER, block data (assuming raw radio BER 10-3)
<1.5 × 10-10 errors/bit
Table 2. Measured performance summary.
same for transmit and receive mode, which
minimizes dead time between receiving and
transmitting packets.
The output power of the Tx power amplifier is register programmable in <3 dB steps
from -4.5 dBm to -17 dBm (into a 500 
load). Internal antenna-matching capacitor
banks on all RF inputs allow for fine-tuning
the matching network for maximum delivered
output power for a given power setting and
optimum receiver noise figure. The antenna
tuning is an automatic calibration that uses a
peak-detector coupled to an ADC along with
a state-machine for calibration control.
The 400 MHz receiver subsystem amplifies the MICS band signal and downconverts
from the carrier frequency to the IF. The lownoise amplifier (LNA) gain is programmable
from 9 dB to 35 dB. Higher gain settings are
recommended for implanted medical device
transceivers while the lower gain settings may
be applicable to base station transceivers that
choose to use an external LNA. Programmability of LNA and mixer bias currents
provides further flexibility in optimizing for
desired linearity (IIP3), power consumption
and noise figure.
A polyphase IF filter is used to suppress in-
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706RFDF1.indd 24
terference at the image frequency and adjacent
channels and limit the noise bandwidth. Limiters and a received signal-strength indicator
(RSSI) block follow the polyphase filter. The
RSSI measurement is converted by a five-bit
ADC and may be read by the industry-standard
SPI interface. This is useful for performing the
MICS clear-channel assessment procedure.
Note that an external instrument must first
determine a suitable usable channel via a
process of clear-channel assessment defined
in the MICS standards.
A specific protocol customized for high
reliability medical applications has been developed. This protocol is handled by the MAC
and includes the following main features:
 Correction and detection of errors using Reed-Solomon forward error correction
(FEC) and cyclic redundancy code (CRC)
error detection. The effective BER after FEC
and CRC is better than 1.5 × 10-10 given a raw
radio BER of 10-3.
 Automatic retransmission of data blocks
in error and flow control to prevent buffer
overflow.
 Capable of sending MICS emergency
command and high priority messages.
 Handling of link watchdog to ensure
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link is shutdown after five seconds without
successful communication.
 Provision of link quality diagnostics and
control of automatic calibrations.
Ultralow-power wake-up receiver
Most implant applications will infrequently
use the MICS RF link due to the overriding
need to conserve battery power. In very lowpower applications, the transceiver will be
asleep in a very low current state for the majority of the time. Systems that use the MICS
band must wait for the base station to initiate
communications following a clear channel
assessment procedure, except when sending
an emergency command. Periodically, the
implanted transceiver should listen for a base
station that wants to begin communication.
The wake-up system uses an ultralowpower RF receiver operating in the 2.45 GHz
SRD band to detect and decode a specific
data packet that is transmitted from a base
station and then switch on the supply to the
rest of the chip. The chip may also be started
directly by pin control as would be needed for
a base station starting up, an implant sending
an emergency command or an implant using
an alternative wake-up system.
Conclusion
Ultralow-power wireless technology is
key for a range of implanted medical devices, including pacemakers, defibrillators,
neurostimulators, drug infusion systems,
diagnostic sensors and the rapidly growing
implanted diabetes monitor. However, as
implanted communication systems evolve to
support advanced diagnostics and therapies,
it’s critical that wireless performance does
not impact the battery life of an implanted
medical device.
References
1. FCC rules and regulations 47 CFR
Part 95, subparts E (95.601-95.673) and I
(95.1201-95.1219) Personal Radio Services,
November 2002.
2. ETSI EN 301-839, parts 1 and 2 and
ETSI EN 301-489 part 27.
ABOUT THE AUTHOR
Peter D. Bradley is systems engineering
manager with Zarlink Semiconductor’s
Ultra Low-Power Communications Division. Bradley holds a bachelor of engineering and master of biomedical engineering
from the University of New South Wales,
Australia, and a PhD in medical physics from the University of Wollongong,
Australia. He can be reached at Peter.
[email protected].
June 2007
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