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Hardware Design for Realization of Smart Sensor Network
A Proposal to the Army Research Laboratory PEER Program
UMCP Researchers: Professor Martin Peckerar and Professor Neil Goldsman, Dept. of Electrical and Computer
Engineering
ARL Researchers: Mr. Luke Currano, Dr. Nibir Dhar and Dr. Madan Dubey
I. Background
Advances in micro-electrical-mechanical systems (MEMS), coupled with new optical devices, present enormous
possibilities in the areas of sensors and energy harvesting. Marrying the MEMs and optical sensors (such as IR
detectors) with smart electronics can also open new doors in novel machine vision technology such as neuromorphic
spectrally agile and retinal sensors. Further, nano-retina sensor concepts could benefit significantly by the combination
of new electronic interfaces/protocols that are likely to evolve through this effort. In view of the above thoughts, sensor
interface ICs (in the form of ASICs, microcontrollers, DSP, FPGA and/or ADC) can play a vital role in making sensors
smarter, and to work effectively in a particular application by amplifying, pre-processing, filtering, and correcting the
sensor's signal; eliminating non-linearities and compensating for environmental factors (such as temperature or
humidity) that can impair the sensor's measurement accuracy (particularly for PZT MEMs sensors), thereby
significantly reducing sensor-signal post-processing requirements, and facilitating the sharing of sensor data with the
host back-plane processors.
The Army Research Laboratory has a leading program on the development of new MEMS structures, and IR sensors.
These state of the art sensors, actuators and energy harvesters are now ready to be integrated into systems where their
benefits can be realized. Using these new devices, we plan to design and fabricate complex distributed smart sensor
networks. As a long term goal, we propose to develop a distributed network of small smart sensors that can monitor the
environment, communicate with each other, locate sensed objects, perform distributed computations, and reach joint
decisions by fusing the data the individual sensors acquire. These sensors could be placed in small UAVs or UGVs for
an ad-hoc and adaptive sensor network. Each of the network nodes will include several MEMS and or optical sensors,
one or two microprocessors, a transceiver, and perhaps an energy harvester. We expect there to be anywhere from ten
to hundreds and perhaps thousands of nodes in the network including UGS. The connectivity of the network will
depend on the transmitting power and the distance between nodes.
Figure 1a illustrates the structure of a single node containing one or more MEMS/optical sensors, an analog to digital
interface, a processor for interpreting the sensor data and controlling the network, and then a transceiver to share and
receive the sensor information with the outside world. Figure 1b illustrates the ad-hoc sensor network. While our long
term goals are to develop sophisticated ad-hoc wireless smart sensor networks that may include new sensor modalities
that are the results of multidisciplinary technologies such as MEMs/IR, our short term goals are to develop the
electronics necessary to control the MEMS sensor devices, extract the sensed information, and where appropriate
transform it into digital signals for micro-processing. In the long-term however, we hope to add IR/optical sensors to
the network, and develop on-sensor signal processing capabilities that communicate intelligent and relevant
information rather
than
simple
images
and
sensory data.
Figure 1a: Smart Sensor Node;
Network
Figure 1b: Smart Sensor
II. Impact of Proposed Research
We have well developed sensor networks and VLSI design groups at the ECE Dept. of the University of
Maryland. Our program in sensor networks is aimed at developing millimeter scale smart sensor nodes called smart
dust. With this program, we are designing our own analog and digital integrated circuits and fabricating them through
the MOSIS facility. The circuits are for sensing, communication and digital control. This program has a funding level
of more than $2 million over the next 4 years. We also have a program on the development of 3-dimensional integrated
circuits, which is funded at the $1 million level. Both of these programs fit very well with the goals of our proposed
work on electronics for MEMS and Optical Sensor networks with the Army Research Lab. The ARL will be able to
benefit significantly from our past experience with these programs by leveraging many of the techniques that have
been uncovered. Addition of this project will increase the scope of investigation and lay foundation for next
generation of electronics that will enable not only smart sensor network capability, but will also offer circuit concepts
for new sensor modalities and new sensor materials/structures such as PZT/ceramic MEMS devices, nanosensor
electronic interface and 3D electronics to develop integrated light weight heterogeneous sensors for deploying in small
military platforms with smart communication protocols.
III. Research Program: Approach & Milestones
Year I Tasks and Milestones
The focus of our research program in the first year will be to work closely with the MEMS group at ARL to develop
state of the art electronics hardware to interface and control their unique sensors and actuators For the MEMS group it
is important to develop the electronics to interface their unique devices with the outside world. In particular, we plan to
begin our collaboration with the design and development of electronics to help realize the capabilities of MEMS
devices including the Shock Sensor and the Piezoelectric Pressure Sensor. The performance and problems of
Piezoelectric Ceramic devices are quite different from silicon and other semiconductor devices. Therefore, new device
design rules for component architectures will be developed. These issues will be accounted for in our circuit design for
piezoelectric sensors which are described below.
All classes of circuits described above will be designed, fabricated, tested and integrated into the sensor/system
configuration under development at each phase of the program. Each year, the resulting circuit will be optimized for
performance in their chosen application realm.
III. Circuit Development Activity
IIIa. Piezoelectric Pressure Sensor: In a piezoelectric pressure sensor, a piezoelectric crystal is sandwiched between
two conducting plates. Upon deformation of the crystal a polarization will occur and a surface charge will be induced
on the crystal. The charge can then be transferred to capacitor plates giving rise to free charge separated by a distance,
thus creating a voltage source. A major difficulty with this particular capacitive source is that as soon as it begins to
provide current, the capacitor discharges, and the output voltage decreases to negligible values. Another difficulty
arises from the fact that the piezoelectric material/capacitive structure provides charge that is largely fixed by the
piezoelectric coupling coefficient, while at the same time, PZT has a very large dielectric constant. Therefore, while a
relatively large capacitance may result, since the charge is fixed, a relatively small voltage may be induced.
The challenge will be to develop electronics which can sense this small charge and/or small voltage. Another important
issue is that since the voltage source is capacitive in nature, only voltage amplifiers which draw virtually no current
will be appropriate for sensing. Thus, amplifiers will need to be MOSFET based. However, at the same time we have
to be careful with respect to noise. Since the signals we are sensing can be relatively small (micro-volt level or below),
we must be careful not to add additional noise from the circuit. This is especially important over the bandwidth at
which the ARL’s PZT sensors will operate, since at these frequencies, MOS electronics can be sensitive to 1/f (often
called flicker) noise. To minimize our noise, while at the same time sense small signals, one needs to design circuits
which maximize transconductance, but at the same time minimize input capacitance. However, this will be a challenge
since transconductance is proportional to capacitance. We therefore plan to develop an optimization scheme where an
optimal balance between low noise generation and high gain (requiring large input capacitance), and low source
loading (requiring low input capacitive) can be achieved. To realize this we plan to develop a multi-stage topology
with approximately 20dB gain in stage one. Additionally, the amplifier will be bandwidth limited to cover only the
operational frequencies of the PZT sensor, and thus reject noise from outside the band of interest. Optimization
programs will be developed using the CAD tool MATLAB. Circuits will be designed with the aid of the CAD program
Cadence, and submitted to the MOSIS foundry service for fabrication; testing will be performed both at UMCP and
ARL laboratories.
IIIb. Analog to Digital Conversion with Range Compression for MEMS: The signals coming from the MEMS devices
will be analog. However, it is often convenient to process theses signal digitally. We therefore plan to develop analogto-digital converters for this purpose. The second circuit employed is a novel “companding” (ADC). This circuit is
based on the standard “flash” design, but the ladder resistances are scaled to perform any degree of scale compression.
The compander is fairly linear at low signal inputs, but it achieves any level of desired compression at high signal
input levels. This creates an enormous increase in dynamic range of the ADC. We have actually fabricated this circuit
and have demonstrated its high-speed performance (>100MHz) using the MOSIS AMI 0.5 micron process. The basic
architecture and chip layout are shown in Figure 2:
Figure 2. “Companding” flash ADC. The resistor “weights” are
set to create any desired compression function.
IIIc. Control Circuits for MEMS devices: In addition to ADC circuits, we will also provide control circuits for MEMS
devices. For example, the ARL MEMS group is interested in controlling their MEMS Shock Sensor. This sensor closes
a circuit when a critical acceleration is reached. To detect the closed circuit, we will apply a voltage to the
accelerometer terminal which in turn will source a signal to a transimpedance amplifier which will provide a trigger
signal to a comparator threshold detector circuit. This comparator will then activate a signal to a current source which
will provide the energy to the thermal actuator to release the latch.
Year 2: We will develop our own sensor nodes using a combination of existing IC’s, and ones that we build and
design at ARL and UMCP. The control and sense electronics will be developed using CMOS technology, designed
with Cadence, and fabricated through MOSIS. Physical interfaces between MEMS and Optical sensors using standard
bonding methods. In year two, we plan to expand our research and development of Smart Sensor Networks by adding
optical sensors, as well as energy harvesting techniques. Below we summarize circuits we plan to develop in Year 2 of
the program.
Circuits for Energy Harvesting: To store energy harvested using the Piezoelectric MEMS vibrational energy
reclamator we will use a full bridge rectifying circuit in series with an energy storage capacitor. Our circuit will be
calibrated to the output impedance of the reclamator.
Voltage and Current Controllers for RF MEMS Switches & Phase Shifters: We plan to sense the change in capacitance
and resonant frequency of the piezoelectric devices. This will be achieved by comparing the signal response of the
piezoelectric device to a known reference. Our plan is to use ultra-stable band-gap referenced supplies to create the
drive voltages.
High Dynamic Range Readouts in the Presence of Large Background Signals for Optical Sensor Arrays. The main
issue here is the cancellation of the large background signal current. This is a well-known problem in infrared optical
sensing, where the thermal backgrounds are enormous. It is necessary to store, or “memorize,” a time-integrated DC
current from the “sky” (or some background region not collecting data from the region of interest), and to subtract that
current from the sensor output when the sensor is switched to the actual scene. There are two approaches in general
use. The first is known as “charge skimming” in which an active current source is used to withdraw (or “skim”) a fixed
amount of current from a readout node. The second approach requires the “storage” of a background current to be
subtracted from the total current generated by a sensor trained on a target scene. We have chosen the latter as our
approach of choice as it offers the possibility of feedback stabilization and low noise.
Year 3: The nodes will be assembles into planar, multi-chip modules. The multi-chip modules will be prototyped
using a 100-micron resolution pick and place machine. The nodes will be programmed and the sensor network will be
established.
Years 4 & 5: We will transform the planar multi-chip module smart sensor nodes into tiny wireless smart
sensor nodes using 3D integration of integrated circuits. The 3D integration will be achieved by first
designing and having our own chips fabricated through MOSIS. The chips will be specially designed for 3D
implementation, requiring development of new 3D design rules and establishing of specific symmetries for
3D interconnects between chips. 3D interconnects will be facilitated by first thinning the SOI CMOS chips.
We have engaged in similar process in collaboration with MIT Lincoln Laboratories.
Annual Budget:
Graduate Research Assistant focusing on Piezoelectric Circuits:
½ Graduate Research Assistant focusing on ADC Circuits
Faculty salary guiding overall program:
45K
23K
27K
Total:
95K
MARTIN PECKERAR
Dr. Peckerar received a B.S. from Stony Brook University, and his M.S. and Ph.D. degrees from the
University of Maryland. In 1976 he joined the Westinghouse Advanced Technology Laboratory where
led a group working in advanced MOS process development. At Westinghouse, he developed the deepdepletion CCD for x-ray and for IR imaging. In 1981, he became head of the Nanoelectronics
Processing Facility at the Naval Research Laboratory (NRL) and, subsequently, head of the Surface and
Interface Sciences Branch. Here, he developed devices for deep-UV imaging and was co-inventor of the
laser-plasma source for x-ray lithography. This source is the primary radiation source used by the Intelled EUV consortium. He has been Principle Navy Technical Officer on the DARPA Advanced
Lithography Program (1989-2003). He was also assigned the role of US Navy consultant to the State
Department on issues relating to strategic arms control for electronic weapons systems. Dr. Peckerar is
now Professor of Microelectronic Engineering at the University of Maryland.
His current research continues to be centered in the analog and mixed signal design. In particular, he is
active in incorporating new materials systems and processes into the system-on-a-chip tool-set. He has
developed algorithms for e-beam proximity control, which are essential for e-beam mask manufacture.
He was the co-inventor of the polysiloxane self-assembled film imaging process. He has also developed
instruments for improvement of e-beam pattern placement using local-fiducial networks. He is also an
expert in the area of imaging system technology. Among his achievements in this area is the
development of a maximum-entropy image reconstruction chip. This chip represented the first
application of entropy regularization to integrated circuit signal processing. He has developed fastFourier chips based on neural net principles and a tomographic imager chip (also based on maximum
entropy principles). Most recently, he is developing “super-capacitor” power sources for distributed ad
hoc sensor arrays. He is co-author of the textbook Electronic Materials: Science And Technology. editor
of the book Synthetic Microstructures in Biological Research, and co-author of the book The Korean
Electronics Industry. Dr. Peckerar was elected a Fellow of the IEEE in 1993.
NEIL GOLDSMAN
Summary of Activities in VLSI Design
Neil Goldsman is a professor in the Electrical and Computer Engineering Department at the University
of Maryland at College Park, where he directs the Mixed Signal VLSI Design Laboratory and the
Semiconductor Simulation Laboratory. He received his Ph.D. with a major in Electrical Engineering and
a minor in Applied Physics from Cornell University. He has more than 120 publications, and is the
principal investigator on research grants and contracts that total more than $1million for current fiscal
year.
Dr. Goldsman regularly teaches VLSI design, and has introduced into the University of Maryland
curriculum two new courses on the subject: ENEE408D (Mixed Signal VLSI Design, a senior capstone
class) and ENEE614 (Radio Frequency VLSI Design, a second year graduate class). He also introduced
ENEE306 (Electronics Circuits Design Lab) and wrote the text for the course.
Dr. Goldsman currently has two sponsored research programs in the area of mixed signal VLSI design.
One program is on developing the electronics to achieve 3-dimensional integrated circuits; the other
program is to develop the hardware and integrated circuits for distributed millimeter scale smart sensor
nodes for distributed sensing and computational networks. In the course of these programs, Goldsman’s
research group has designed and fabricated more than twenty five custom integrated circuits. The design
and layout is performed in the laboratory, which ultimately yields a GDS2 file, which contains a blueprint of the integrated circuit. This file is then submitted to the MOSIS facility for IC fabrication. Once
fabricated, the chip is sent back to Dr. Goldsman’s lab for testing. Various types of IC’s have been
designed and fabricated. Chips for smart sensor networks have focused on communication IC’s
including voltage controlled oscillators (VCO) and phase-locked loops. Goldsman’s smart sensor
network activities also involve energy harvesting using ambient electromagnetic waves. In this effort,
his group is developing VLSI inductors and transformers for energy storage circuits. Goldsman’s group
has also developed numerous IC’s for use in 3D integrated circuits. In one particular circuit, his group
was chosen to contribute a design for a unique 3D integration fabrication run that was performed at MIT
Lincoln Labs. This circuit contained 3 layers. On the top layer, we design a system of photodiodes for
energy harvesting. The next layer contained a large system of storage capacitors, which worked to
power the VCO circuit implemented on the bottom level. Other interesting circuits that were recently
designed and fabricated under Goldsman’s supervision include temperature sensor arrays, and frequency
counters for use as on-chip instrumentation circuitry in the 3D-integration program. Dr. Goldsman’s
publications in the area of VLSI include papers on optimized on-chip inductors (see for example, Bai,
Dilli, Goldsman, Metze, ISDRS 2003), and on the heat generation in integrated circuits (see for
example, Akturk, Goldsman, Metze, Solid State Electronics, 2005). Attached is a list of the IC’s that
have been designed and fabricated under the direction of Dr. Goldsman in the last several years.
Integrated Circuits Designed and Fabricated Under Supervision of Neil Goldsman
No. MOSIS
MOSIS Designer(s), Date Description
Proj. No.
Fab.ID
--------------------------------------------------------------------------1. 65008
T26BDF
Yun, Goldsman, Jun'02
Monolithic FSK
Transmitter
2.
65759
T2AKAV
Yun, Goldsman, Oct'02
3.
65760
T2AKBJ
Yun, Goldsman, Oct'02
4.
65761
T2AKBN
Yun, Goldsman, Oct'02
5.
65762
T2AKBD
Yun, Goldsman, Oct'02
Substrate noise
coupling analysis
6.
66962
T33AAC
Yun, Goldsman, Apr'03
Substrate noise
coupling analysis
7.
66963
T33AAD
Yun, Goldsman, Apr'03
Inductors/substrate
noise coupling analysis
8.
64639
T26ZAY
11. 68785
T3AJAL
13.
68865
T3AJBV
Akturk, Parker,
Goldsman Oct'03
Heaters and
temperature sensors
14.
68866
T3AJCD
Akturk, Parker,
Goldsman Oct'03
Heaters and
temperature sensors
15.
68893
T3CUCF
16.
70241
T46TAG
Dilli, Goldsman, Jun'02 Internal/external ring
osc., counters
(Measurements on the loading effects
of off-chip connections and
packaging).
9. 65046
T26BBJ
Dilli, Goldsman, Jun'02 Internal/external ring
osc, counters
(Measurements on the loading effects
of off-chip connections and
packaging; delay measurement structures).
10. 65765
T2AKAS
Dilli, Goldsman, Oct'02 Three dimensional
ring osc., counters
(Chip designed for post-processing to create three-dimensionally
integrated ring oscillators and counters; measurements on the loading
effects of three-dimensional interchip vias.)
Dilli, Goldsman, Oct'03 On-chip inductor
structures
12. 68786
T3AJAM
Dilli, Goldsman, Oct'03 On-chip
digital/analog
coupling structures
(Chips designed for RF-probe station measurements: On-chip
digital and analog and RF structures, substrate coupling, digital
noise.)
Akturk, Parker,
Heaters and
Goldsman Oct'03
temperature sensors
(Chips designed with on-chip heating elements like switching
digital circuits or polysilicon resistors and diodes as temperature
sensors, to study chip heating.)
Dilli, Goldsman May'04
Inductors
17.
70242 T46TAF
Dilli, Goldsman May'04 Inductors
(Inductor structures on different substrates; de-embedding
structures; for measurements on the substrate doping effect on
inductance.)
18.
70839
T47FBH
Akturk, Parker,
Dilli, Goldsman Jul'04
Heaters and
temperature sensors
19.
70840
T47FCA
Akturk, Parker,
Dilli, Goldsman Jul'04
Heaters and
temperature sensors
20.
70842
T47FCD
Akturk, Parker,
Dilli, Goldsman Jul'04
Heaters and
temperature sensors
(Chips designed with on-chip heating elements like switching
digital circuits or polysilicon resistors and diodes as temperature
sensors, to study chip heating.)
21.
71656
T4BPAT
Dilli, Goldsman Nov'04
Inductors
22.
71657
T4BPAV
Dilli, Goldsman Nov'04
Inductors
23.
71690
T4BPAU
Dilli, Goldsman Nov'04
Transformers
24.
71691
T4BPAW
Dilli, Goldsman Nov'04
Inductors
25.
72095
T51ABC
Dilli, Goldsman Jan'05
Inductors
26.
72096
T51ABA
Dilli, Goldsman Jan'05
Inductors/transf.
27.
72097
T51ABB
Dilli, Goldsman Jan'05
Inductors/transf.
(Inductors and transformers with varying substrates, different
coupling geometries; 3-D inductors; tunable inductors/transformers;
de-embedding structures.)
NOTE: All the chips listed above use the AMI C5N (0.5 micron) process
except 64639 (T26ZAY), which uses the AMI ABN (1.5 micron) process.
28.
N/A
N/A
Dilli, Goldsman May'05 3D self-powered
"dust" particle
(This design is submitted to and is currently in fabrication at the MIT
Lincoln Labs. It is based on the SOI technology and three-dimensional
stacking technique developed there. It includes three planar chip
(layer) designs: The first one is a photodiode array for power
harvesting, the second one houses a capacitor for power storage and
the third layer is a local oscillator to be powered by the other two
layers. The layers are connected by vertical through-vias. The
complete stack is expected to be about 250x250x800 microns in size.)