Safety is a primary concern for robots operating in space. The tri-mode sensor addresses that concern by employing a collision avoidance/management skin around the robot arms. This rf-based skin sensor is at present a dual mode (proximity and tactile). The third mode, pyroelectric, will complement the other two. The proximity mode permits the robot to sense an intruding object, to range the object, and to detect the edges of the object. The tactile mode permits the robot to sense when it has contacted an object, where on the arm it has made contact, and provides a three-dimensional image of the shape of the contact impression. The pyroelectric mode will be added to permit the robot arm to detect the proximity of a hot object and to add sensing redundancy to the two other modes. The rf-modes of the sensing skin are presented. These modes employ a highly efficient magnetic material (amorphous metal) in a sensing technique. This results in a flexible sensor array which uses a primarily inductive configuration to permit both capacitive and magnetoinductive sensing of object; thus optimizing performance in both proximity and tactile modes with the same sensing skin. The fundamental operating principles, design particulars, and theoretical models are provided to aid in the description and understanding of this sensor. Test results are also given

Chauhan, D. S.

Dehoff, Paul H.

English

NASA Technical Reports Server

MAGNETO-INDUCTIVE SKIN SENSOR FOR 
ROBOT COLLISION AVOIDANCE 
(A NEW DEVELOPMENT) 
BY 
Dr. D.S. Chauhan 
Prof. Paul H. DeHoff 
ANNUAL REPORT 
CONTRACT 
NAG 5 1053 
Department of Mechanical Engineering 
University of North Carolina 
At Charlotte, NC 28223 
- 
( EAS I - C R -  1854 C2) HAG 1yI610-I I L L C I I I  V E SKI N N89-25444 
S E b S C h  PCB 60EOI C C I L X I S 1 C ) I  A F C I I A A C E :  A HEY 
L E V E L C f B E I I  d m u a l  fie5ort (hcrth  Carol ina  
Cniv,) 12 F CSCL IUB Unclar 
G3/35 0277710 
https://ntrs.nasa.gov/search.jsp?R=19890016073 2020-03-20T01:43:54+00:00Z
A New Development To 
Magneto-Inductive Skin Sensor For 
Robot collision Avoidance 
D.S.Chauhan Paul H. DeHoff 
ABSTRACT 
Safety is a primary concern for robots operating in space. The tri-mode 
sensor, being developed in-house at the NASA/Goddard Space Flight Center, 
addresses that concern by employing a collision avoidance/management skin 
around the robot arms. This RF-based skin sensor is at present dual mode 
(proximity and tactile). The third mode, pyroelectric, will complement the other 
iwo. The proximity mode permits the robot to sense an intruding object (including 
a human being), to range the object (in time to permit the robot to react) and to 
detect the edges of the object (with sufficient directionality and resolution to permit 
the robot to go around it). The tactile mode permits the robot to sense when it has 
contacted an object, where on the arm it has made contact and provides a three 
dimensional image of the shape of the contact impression. The pyroelectric mode 
will be added to the skin to permit the robot arms to detect the proximity of a hot 
object and to add sensing redundancy to the other two modes. This will be 
accomplished by adding a layer of pyroelectric material over the RF-based sensor 
which will "see through it". The sensing system will perform despite sun glint, 
temperature extremes and vacuum (conditions which predominate in space). Its RF 
field is sufficiently weak and low frequency that it will not disturb other 
instruments. And, since the RF field is sinusoidal, unfriendly EMI noise can be 
filtered out. Magnetic objects are easily identified. The sensing system would have 
difficulty detecting objects that are totally non-conducting and with a dielectric 
constant of one; but it is extremely unlikely such materials would exist in isolation 
on the Space Station or a space vehicle. 
In this report the RF-modes of the sensing skin are presented. These modes 
employ a highly efficient magnetic material (amorphous metal) in a novel sensing 
technique. This results in a flexible sensor array which uses a primarily inductive 
configuration to permit both capacitive and magnetoinductive sensing of objects; 
thus optimizing performance in both the proximity and tactile modes with the same 
sensing skin. The fundamental operating principles, design particulars and 
theoretical models are provided to aid in the description and understanding of this 
sensor. Test results are alsd given. 
I. INTRODUCTION 
The objective is to develop a sensing skin that will prevent the robot arms 
from colliding with objects in space; particularly human beings. It is essential that 
this sensing system be able to function reliably in the extreme environment of space 
and that it not be disturbed by or create disturbances in neighboring NASA 
instruments. To date, this has been a vexing problem for NASA engineers. Our 
evidence indicates that an approach based on an array of low rf capacitors is 
promising. This approach will satisfy both the proximity and the tactile modes. A 
thin sheet of polyvinylidine fluoride (PVDF) will be added later to provide a 
temperature sinsing capability and complete the third mode. 
I1 FUNCTIONAL REQUIREMENTS 
follows: 
1. 
2. 
3. 
4. 
5. 
6 .  
At this point the functional requirements are general and address proving the 
suitability of the sensing principle for space use as a robot collision-avoidance sensor 
rather than worrying the details (such as out-gassing materials etc.). These are as 
The sensor should be able to detect a human at ranges of 12 in. (30.5 cm) to 
give the robot sufficient notice to stop. 
The sensor should be able to detect the near-range of an object sufficient to 
avoid collisions and to find the object edges. 
The sensor should be able to detect the edges of an object in the near-range 
sufficient to avoid robot collisions. 
The sensor should be able to detect contact and where and how hard the 
contact is. 
The sensor should be able to detect the presence, direction and temperature 
of hot objects. 
The sensor should not interfere with other instruments nor permit itself to 
be interferred with. 
I11 PRINCIPLES OF OPERATION 
The general function of the robot skin is illustrated in fig. 1. A constant 
voltage source drives current through a resonant tank circuit in series with a 
resistor. The frequency of the signal is near resonance and is optimized for sensor 
sensitivity. The individual columns and rows of the array are mouned on the robot 
arm. These are individually and sequentially connected to the circuit, through a 
demultiplexer arrangement, at a point between the tank circuit and the resistor. The 
tank circuit and the resistor form a voltage divider with the sensor array poised 
between the two. The sensing element (column or row) of the sensor array is 
essentially a capacitive place at the potential of the circuit. When an object comes 
near the sensing plate(s), a leakage capacitive coupling to ground is formed, the 
balance of the voltage drivider is disturbed, and we observe this disturbance and 
intepret it as proximity sensing. Since we can individually scan rows and columns, 
we can locate the edges of the object and range it so provided it is either a conductor 
or dielectric. If the object touches a sensing element, the capacitive plate is pushed 
nearer the grounded robot arm and we observe a change in the potential on the thin 
conductor near the robot arm. We interpret this change as tactile sensing. Fig.2 
shows the physical characteristics of the sensory array. Fig.3 shows the development 
of the equivalent circuit. 
IV MODELLING 
An electromagnetic sensor array located over an imperfectly conducting space 
can be modelled using the Dodd and Deeds theory1 and low frequency quasi-static 
theory. The quasi-static principle is applicable when the frequency is low and the 
driving signal is small. The voltage drop across the drive coil behaves as a charge 
conductor and current behaves in the similarity of drive signal. The a.c. 
characteristics of circuit is unperturbed but coupling characteristic only get changed - 
in proximity. Proximity of drive soil behaves quasi-static due to electrostatic flux 
present in the surroundings. The extension of quasi-static bus is also possible. The 
voltage occupies the extended surface and completely behaves as a changed surface. 
This peculiar quasi-static characteristic is used for skin sensor. Copper strips of 1" 
width are placed and glued horizontally and vertically in order to build array. Fig. 
photo of skin. Electro-static potential is brought to this array and coupling is 
experienced on resonant circuit. Movement of objects including human body is 
seen upto 1-2 feet range. It has directionality in coupling activity. The column or 
row in front of an object show more variation in output therefore array can be built 
ot and can be intefaced to a multiplexer for its data separation and position sensing 
of an object. The array and coil connections are shows in fig. 2. The mathematical 
expressions of electrical cuicuits are derived for both quasi-s tatic and non-static 
behavior are presented in first semi-annual report. 
V EXPERIMENTATION/CONCLUSIONS 
The sensor was originally envisioned as an eddy current sensor with 
magnetoinductive coils mounted on the robot arm (see Fig. 4. Proximity sensing 
performace was both better and different than was expected. Experimentation 
revealed that it did sense inductively (using eddy currents from conductors and/or 
magnetic flux from ferromagnetic materials); but the dominant effect was 
quasistatic/capacitive. There was no evidence of sensing due to an antenna or 
radiation effect and this was to be expected considering the long wave length of the 
rf signal. A series of experiments was conducted over a period of several weeks to 
ARRAY CAPACITIVE PLATES 
- 
FIGURE 1. SENSOR CONCEPT (PROXIMITY/TACTILE) 
. CAPACITIVE COUPLING 
- 
I 4 4 
$ I I I ---- 
-r- V OUT -_--- 
/ 
i 
(PROXIMITY) n 
- - 7 - -  I ‘* 
I 
I 
I 
V OUT (PROXIMITY) :I 
r--- (TACTILE) 
-- I- - I \  h I  . -... < 
CIRCUIT 
CAPACITIVE COUPLING 
COMPLIANT INSULATING 
W E E N  PLATES 
p’ 
SENSOR ARRAY 
\ 
v OUT CAPACITIVE PLATE 
(PROXIMITY) CROW OR COLUMN 
A) PROXlMlTYlTACTlLE ACTION 
FIGURE 3. DEVELOPMENT OF EQUIVALENT CIRCUIT 
7 -., NO* f;$WM a 
I 
SPACING FROM ROBOT ARM 
OBJECT TO BE 
DETECTED 
' INDUCTOR (5) 
WIT" METGLAS CORE 
FIGURE 4. EXPERIMENTAL SETUP 
LEAKAGE THROUGH OBJECT (SIGNAL) 
--- / 
-1-- 
I 
TURN-TO-TU RN 
I CAPACITANCE 
----- 
-1--- 
I 
I I 
I 11 BACKGROUND LEAKAGE 11 
A. DISTRIBUTED COMPONENTS 
B. LUMPED COMPONENTS 
FIGURE 5. EQUIVALENT CIRCUIT OF EXPERIMENT 
, 
X Y=O 
CHARGED + + + + + + + + SURFACE 
Y r REGION I (SPACE) 
Y=Y1 
- - - - - - - -  - NEAR 
SURFACE 
REGION I I  (OBJECT) 
Y=Y2 - - - - - - - -  - FAR 
- - SURFACE 
REGION 111 (SPACE) 
FIGURE 6. PROXIMITY SENSING 
arrive at the conclusions described above. However, it is felt that the results of the 
single set of experiments described below gives a good summation of the 
phenomenon which makes the sensor work and its potential capabilities. 
hand nearer for one set of measurements. The experimentor was isolated from 
gound. For the second set of measurements, a small, gounded, conducting cylinder 
was moved near the sensor and for the third set of measurements, the small 
cylinder was ungrounded. Table 4, below, shows uncalibrated measurements. They 
were measured using distances off a meter stick and estimated readings off a CRO. 
These were sufficient at the time to establish the dominant sensing phenomenon 
and to get an estimate of its performance potential. Some initial conclusions are as 
follows: 1. The sensor can detect a human at ranges in excess of 12 in (30.5 a). 
Thus it can detect an object which is a poor conductor; but has a high dielectric 
constant (81) and is a large charge source. Clearly the sensor has potential as a safety 
device for humans in space and clearly its means of sensing is capacitive; not 
inductive. 2. The sensor detects grounded small cylinders much better than 
ungrounded; but the capacitive effect is. Therefore we can again see that the 
capacitive effect is dominant; particularly at long ranges. And, we can see that a 
relatively small diameter conductor, if grounded, or connectyed to a large charge 
source can easily be detected at relatively long ranges. This also shows the sensor's 
potential as a safety device in space. Measurements taken approaching the coil 1.5 in 
(3.8 cmO above its centerline show the readings dropping off considerably at short 
ranges so we can see the systems' potential as a near-range edge detector. Variations 
in the azimuth field results which are similar to those given at zero azimuthal 
angle. 
received our best performance at 80 Khz and this turned out to be near a high "Q" 
resonance. We were dealing with a tuned circuit and not merely an inductor. The 
equivalent circuit, therefore, is as shown in fig. qand the measurements and 
mathematics supports this interpretation. Why not, then, take the coil off the robot 
arm, and create the same effect using a remote tuned circuit with capacitive plates 
on the arm? This reconfiguration was tried and it worked. The equivalent circuit * 
developed in fig.3 and the capacitive plates on the arm shown in fig.2. reflect this 
conclusion. We are now experimenting with eliminating the metglas coil and 
replacing it with some off-the shelf very high "Q" oscillators operating near 
resonance, and stabilizing them with phase-locked loops, where appropriate. 
Variable frequency oscillators will also be employed, a beat signal will be developed 
and the frequency of this beat signal will contain the necessary detection 
information. This should improve many performance parameters of the sensor 
range, sensitivity, stability, and resistance to effects of external noise. 
Tactile sensing has always worked exceedingly well and has required very 
little development. Essentially, pressing on a capacitive plate pushes it closer to the 
grounded robot arm and this is detected immediately. 
An experimentor stood out of the range of the sensor and then moved his 
Closer examination of the experimental setup shown in fig.$ indicated we 
Table f=80KHz. Azimuth = oo 
Elevation above coil centerline = 0 in, 0 an. 
Distance from coil to 
object 
------------------- 
in 
1 
2 
3 
6 
9 
12 
18 
cm 
----. 
2.5 
5 
8 
15 
23 
31 
46 
OBJECT 
Ungrounded 
Human 
1.9 v 
360 mv 
150 mv 
17.5 mv 
7.1 mv 
4.4mv 
8.0 mv 
Grounded Al cylinder 
2.75 in dia.x 4.5 in long 
0.52 v 
250 mv 
110 mv 
17.5mv (est) 
7.5mv 
5 mv 
Jngrounded Al cylinder 
2.7 in dia. x 4.5 in long 
0.39 v 
60 mv 
40 mv 
2.5mv 
--I 
--- 
VI. FUTURE PLANS 
We next plan to put a sample of the skin on a PUMA 560 arm and 
demonstrate its detection capability (proximity and tactile). Following this the heat 
detecting film, Polyvinylidine-Flouride (PVDF), will be placed outside of the rf dual 
mode system and the capacitive effect will perform as if the PVDF will complete the 
tri-mode sensor hardware. The software and detection and collision avoidance 
algorithms will represent, however, on a new phase in the development and this 
will be an extensive one. 
References: 
1. Pugh, E.M. and E.W. Pugh. "Principles of Electricityand Magnetism". 2nd ed. 
Addison-Wesley Publishing Co. Reading Mass 1970, Chapter IV 
2. The impedence of a coil near a conductor. Proceeding of the National Electronics 
Conference, Vol. 12, pp. 188-196, 1956 - Waidelich, D.L., Ranken, C.J. 
3. Russell, T.J., Schuster, V.E. and Waidelich, D.L. The impedance of a coil placed 
on a conducting plane. Trans of AIEE, Communication and Electronics, Vol. 81, 
pp.232-237 
4. B.A. Auld, J. Kenney and T. Lookabaugh, "Electromagnetic Sensor Arrays- 
Theoretical Studies," Review of Progress in Quantitative Nondestructive 
Evaluation, Vo1.5 D.O. Thompson and D.E. Chimenti, Eds. (Plenum Press, New 
Yord, 1985 
5. John. M. Vranish, "Magnetoinductive Skin For Robots". Sensor-86; MS 86-759- 
34, Nov. 11-13 Detroit, MI 
6. Fan, L.S. White, R.M. and Muller, R.S. "A Mutual Capacitive normal and shear 
sensitive tactile sensor IEEE Int. Electron Mg. , pp.220-222, 1984 
7. Berec, A, Soykan, 0, and Neuman, M.R. ,"A Multi-elemental Capacitive force 
sensor", Proc. Annu. Conf. Eng. Med. Biol, 29:101, 1987 
8. Boie, R.A. "Capacitive impedance readout tactile image sensor", IEEE Int. Conf. 
Robotics Autom 370-378, 1984 
9. Micromaching and micropa,Ling of transducers - by H.Ko and D.G. Flemming, 
NY: Elsevier. B.A. Auld, A.J. Bahr 
10."A Nobel Multifunction Robot YSensors", IEEE Conference 1986 on Robotics, 
pp.1791-97 
11.Tactile Sensors for Robotics & Medicine-by John G. Webster, John Wiley & 
Sons, 1988 


Magneto-inductive skin sensor for robot collision avoidance: A new development

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