Radiant energy – Invisible radiant energy responsive electric signalling – Infrared responsive
Reexamination Certificate
1999-02-01
2001-09-25
Hannaher, Constantine (Department: 2878)
Radiant energy
Invisible radiant energy responsive electric signalling
Infrared responsive
C250S338200
Reexamination Certificate
active
06294784
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to pyroelectric sensors and, more particularly, to a method of determining the polarization state of a pyroelectric element by applying an AC signal to the element and calculating, multiple times, the hysteresis loop switching energy of the element for a predetermined time frame, and comparing it to a reference switching energy at a corresponding reference temperature.
2. Discussion of the Related Art
A certain class of sensors make use of ferroelectric materials, and their pyroelectric effect for detection of temperature change. Sensors of this type have a wide range of applications, such as imaging in low visibility conditions, for example, poor weather conditions, night vision, etc. A ferroelectric material is a dielectric material that has a temperature dependent spontaneous electrical polarization in the absence of an externally applied electric field which can change state with the application of a critical field, where the polarization magnitude and direction within the ferroelectric material is identifiable by a hysteresis loop. The orientation of the polarization of the material can be changed by applying a reversing external electric field to the material. The electric dipoles within the material, that identify the orientation of the polarization, change when the external field is applied and in a proper circuit layout produce a hysteresis loop. Since spontaneous polarization is generally temperature dependent, ferroelectric materials can employ the pyroelectric effect for temperature detection purposes.
Any area of the hysteresis loop, either the entire saturated hysteresis area or merely a region of operation anywhere within the full loop, is representative of the switching energy required to change the polarization states of some or all the dipoles which make up the atomic lattice structure of the material at a given temperature for the specific state of excitation. Any change in radiation incident on the ferroelectric material, if absorbed, changes the temperature, and thus changes the associated loop area.
FIG. 1
shows two charge versus voltage hysteresis loops for a particular ferroelectric material at a first temperature T
1
and a second temperature T
2
. If plotted independent of physical dimensions, the magnitude of an externally applied alternating electric field is given on the horizontal axis and polarization, in charge density, is given on the vertical axis. The area of the charge versus voltage hysteresis loop of a ferroelectric material has dimensions of energy, and the loop area is a direct function of its temperature. The magnitude of the polarization changes with a change in the temperature of the ferroelectric material for a given electric field. A careful review of the two hysteresis loops in
FIG. 1
will show that for the two different temperatures T
1
and T
2
, the area within the loop is different. Consequently, an electrical measurement of the change in area anywhere within the major loop is an electrical signal corresponding to the change of the temperature of the material, and thus of the incident infrared radiation. The effect is of a dynamic nature due to the switching between polarization states of the pyroelectric material, and therefore, when measuring incident radiation, it is necessary to shutter the radiation, to reference the ferroelectric spontaneous polarization before each window opens to the scene.
Heretofore, all of the known ferroelectric/pyroelectric sensors that convert varying radiation energy to usable electrical signals greater than the inherent ambient noise of the sensor system operate in a passive mode. This means that the pyroelectric element operates at a given polarization state which is a function of temperature change, without any deliberate electrical polarization reversal. More specifically, passive pyroelectric detection only interrogates the polarization state of the ferroelectric material typically by measuring the net voltage across a poled capacitor structure, or by small signal AC excitation to determine the permittivity of the material (which is a function of the poled state), or some combination of these two methods. The practice in the industry to compare ferroelectric/pyroelectric sensors has been to measure the pyroelectric coefficient p, which is defined as the partial derivative of the displacement D with respect to the temperature T, p=(&Dgr;D/&Dgr;T) at a given bias field, E
B
. What this means is that for a physical geometry having sensor area A, the amount of coulombs of charge Q is generated per temperature T, and the pyroelectric coefficient p is expressed as: p=(1/A) [&Dgr;Q/&Dgr;T]. Unfortunately, this technique only represents a single cycle around a minor portion of the available signal energy as represented by the hysteresis loop area.
FIG. 2
shows a schematic block diagram of a known pyroelectric sensor system
10
that employs a conventional passive charge generation technique to determine the output of the sensor element. The sensor system
10
includes a chopper
12
that selectively gates radiation from a scene onto an infrared absorber
14
that is part of a pyroelectric element
16
. The pyroelectric element
16
is made of a ferroelectric material that exhibits hysteresis loops which vary with temperature as shown in
FIG. 1
, and represents a single pixel element of the sensor system
10
that combines with other pixel elements (not shown) to generate an image, as is well understood in the art. The discussion herein is directed to an infrared imaging system, but as will be appreciated by those skilled in the art, sensor systems of this type are applicable to detect other wavelengths of radiation, including millimeter waves and microwaves.
The chopper
12
selectively blocks and passes the radiation directed to the pyroelectric element
16
at a predetermined frequency so that the pyroelectric element
16
sees a reference temperature when the chopper
12
is closed, and sees the temperature of the scene when the chopper
12
is open. The difference between the reference temperature and the scene temperature alters the shape of the hysteresis loop as shown in FIG.
1
. The change in charge Q(t)
18
for the two loops is measured separately as a voltage across a sampling capacitor
20
and an amplifier
22
, in a manner that is well understood in the art. Because no external electric field is applied to the pyroelectric element
16
, the measured charge of the pyroelectric element
16
that charges the capacitor
20
for the two loops is the charge Q(t) where the hysteresis loop crosses the positive vertical axis for temperature T
1
and the charge Q(t) where the hysteresis loop crosses the positive vertical axis for temperature T
2
. The sampling capacitor
20
stores the charge from the pyroelectric element
16
only each time the window is opened by the chopper
12
. The effective pyroelectric coefficient p for this design is given as:
p=
(1/
A)[
Q
1
-Q
2
]/[T
1
-T
2
]
In an alternate known design, the small signal level capacitance, i.e. (change in local slope of the Q versus V curve of either a poled or unpoled ferroelectric material) between the charge stored by the pyroelectric element
16
is measured for temperature T
1
and T
2
and then compared.
FIG. 3
shows a schematic block diagram of a sensor system
26
including the chopper
12
, the infrared absorber
14
, the pyroelectric element
16
and the amplifier
22
. Sometimes small bias voltage is applied to the pyroelectric element
16
from a bias source (not shown), and a capacitance meter
28
is used to measure the change in capacitance between the location on the hysteresis loop for both temperatures T
1
and T
2
relative to the bias voltage. Even though a small bias voltage is applied to the pyroelectric element
16
in this design, the mode of operation is still passive because the small bias voltage does not alter the polarization state of the ferroelectric material
Catalan Antonio Buddy
Mantese Joseph Vito
Micheli Adolph Louis
Schubring Norman William
General Motors Corporation
Grove George A.
Hannaher Constantine
Sedlar Jeffrey A.
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