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Claims  |
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What is claimed is:
1. In a receptor for a computerized transaction card containing
microcomputer means, a power transfer coil, and a power transfer
ferromagnetic member adapted, when said card is in said receptor, to flux
link said coil with a transformer primary means in said receptor for
transfer of energy from said receptor to said microcomputer means to
provide therefor both operating power and a clock signal transmitted to
said coil from said receptor, an improvement comprising:
a power amplification circuit adapted to drive the transformed primary
means in response to an oscillator signal of predetermined frequency, the
transformer primary means being connected to a variable voltage source;
means for measuring current flow in the transformer primary and for
providing an output signal (I.sub.a) representing an averaged magnitude of
same; said microcomputer means being responsve to values of P.sub.thresh,
I.sub.q, V.sub.n and C.F., stored in memory means, for performing the
calculations;
P.sub.card =(I.sub.a -I.sub.q).times.V.sub.n .times.C.F.
where:
I.sub.q =quiescent current flow in the transformer primary
V.sub.n =magnitude of voltage source
C.F.=correction factor
P.sub.thresh =threshold power level for the transaction card
and increasing said variable voltage source until P.sub.card exceeds
P.sub.thresh.
2. A method for magnetically coupling a threshold amount of power across a
dielectric interface from a primary coil in a station apparatus to a
secondary coil embedded in a movable electronic transaction card, the
primary coil being a circuit element in a power amplifier connected to a
variable voltage source; comprising the steps of:
i. storing a predetermined value of quiescent current flow (I.sub.q,n) in
the primary coil at each of n voltage source levels;
ii. measuring the magnitude of current flow (I.sub.a,n) in the primary coil
at a particular voltge source level (V.sub.n);
iii. calculating the quantity:
P.sub.card =[I.sub.an -I.sub.q,n ].times.V.sub.n .times.K
where: K is a predetermined scaling factor
iv. terminating the process when P.sub.card exceeds the threshold amount of
power; and
v. increasing the voltage source level and repeating the steps starting at
step ii.
3. The method of claim 2 wherein the station apparatus includes means for
detecting the removal of the electronic transaction card from the station
apparatus and, in response thereto, further includes the steps of:
measuring the magnitude of current flow in the primary coil at each of n
values of voltage source level; and
replacing the stored values of (I.sub.q,n) with the measured magnitudes of
current flow each time the electronic transaction card is removed from the
station apparatus.
4. Improved apparatus for supplying an alternating current signal to a
portable electronic transaction card wherein the apparatus includes a
first coil for coupling the alternating current signal to a second coil
located on the card, and further includes a sensor that provides first and
second sensor voltages in response to the presence and abence of the card
in the apparatus, the improvement comprising:
a first semiconductor device, interconnected to a variable voltage source
through the first coil, for amplifying the alternating current signal;
means responsive to the current flowing through the first coil, for
providing a digital signal reflecting the magnitude of said flowing
current; and
microprocessor means, including memory and stored instructions, responsive
to the digital signal representing the magnitude of the flowing current
and responsive to the sensor voltges, for controlling the magnitude of the
variable voltage source.
5. The apparatus of claim 4, further comprising a second semiconductor
device interconnected to the variable voltage source through the first
coil, said first and second semiconductor devices forming a push-pull,
class B amplifier circuit with the variable voltage source connected to a
center tap of the first coil between said first and second semiconductor
devices.
6. The apparatus of claim 4 wherein the alternating current signal is a
periodic signal whose frequency is an integer multiple of a timing signal
used in the portable electronic transaction card, whereby power and clock
are simultaneously delivered to the card.
7. Apparatus for magnetically coupling an AC power signal from a primary
coil to a movable secondary coil across a dielectric interface, the
primary coil being connected to a voltage source and driven by an
amplifier, the apparatus including means for sensing when the movable
secondary coil is in close association with the apparatus, the apparatus
further including:
means for determining the difference in power delivered to the primary
coil, between the condition that the second coil is in close association
with the apparatus and the condition that it is not; and
means for varying the magnitude of the AC power signal in accordance with
the difference in power.
8. A power transfer arrangement for magnetically coupling a predetermined
amount of electrical power from an amplifier to a load impedance across a
contactless interface, said amplifier including a primary coil connected
to a variable voltage source, the arrangement comprising:
means for detecting the condition that the load impedance is in close
physical proximity to the contactless interface and for providing an
indication of same;
means for determining differential current flow through the primary coil
between the condition that the load impedance is in close physical
proximity to the contactless interface and the condition that it is not;
means responsive to said differential current and to the magnitude of the
voltage source for determining the amount of power being delivered to the
load impedance; and
means for increasing the magnitude of the voltage source during the
condition that the load impdeance is in close physical proximity to the
contactless interface until the delivered power is substantially equal to
said predetermined amount of electrical power.
9. The power transfer arrangement of claim 8 further comprising:
means for measuring the amount of current flow through the primary coil at
various magnitudes of the voltage source during the condition that the
load impedance is not in close physical proximity with the contactless
interface;
memory means for storing said measured amounts of current flow at each of
the magnitudes of the voltage source; and
means responsive to the removal of the load impedance from close physical
proximity with the contactless interface, for repeating the measurement of
current flow through the primary coil at the various voltage source
magnitudes.
10. Apparatus for magnetically coupling AC power from a primary coil to a
movable secondary coil across a dielectric interface, the primary coil
being connected to a voltage source and driven by an amplifier, the
apparatus including means for sensing when the movable secondary coil is
in close association with the apparatus, the apparatus further including:
means for varying the magnitude of the voltage source connected to the
primary coil;
means for measuring active current flowing in the primary coil at various
magnitudes of the voltage source when the secondary coil is in close
association with the apparatus;
means for measuring quiescent current flowing in the primary coil at said
various magnitudes of the voltage source when the secondary coil is not in
close association with the apparatus;
means responsive to the difference between the measured active and
quiescent currents at said various magnitudes of the voltage source for
calculating delivered power; and
means for increasing the magnitude of the voltage source when the secondary
coil is in close association with the apparatus until the delivered
exceeds a predetermined threshold.
11. The apparatus of claim 10 further including means for commencing the
measurement of quiescent current each time the secondary coil is removed
from close association with the apparatus.
12. The apparatus of claim 10 wherein the magnitude of the voltage source
is increased by predetermined discrete steps, the apparatus further
including:
analog-to-digital converter means for converting the measured active and
quiescent currents into ordered sequences of binary digits at each of said
discrete voltage steps; and
memory means for storing the ordered sequences of binary digits. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention relates to equipment that communicates with electronic
transaction cards. More particularly, it relates to apparatus for
delivering a predetermined amount of power to such a card through a
contactless interface.
BACKGROUND OF THE INVENTION
Personal Data Cards (PDC), also known as "Smart Cards," are devices that
include one or more microelectronic chips embedded in a piece of plastic
about the size of a conventional credit card. Typically, the chips include
a microprocessor to perform computing operations and some form of memory,
such as an EEPROM, for storage. Such cards may be used, for example, in a
manner similar to a "debit" card for long distance telephone calls, retail
store purchases and automatic banking machines. Other uses include
personal identification and general data storage which may be modified
from time to time by the card holder or the card issuer. Background
material for such cards can be found in an article entitled "Smart Credit
Cards: the answer to cashless shopping" published in the February, 1984
issue of IEEE Spectrum at pages 43-49; and in an article entitled "Smart
Cards" published in the November, 1985 issue of Scientific American at
pages 152-159.
Power transfer to the PDC is conventionally achieved via metallic contacts
which, unfortunately, are subject to oxidation, corrosion, and the deposit
of surface contaminants that may increase ohmic resistance in one
situation, or create a short circuit between adjacent contacts in another.
Such metallic contacts need to be electrically and mechanically rugged to
provide reliable results over their expected lifetime.
One solution to this general problem is disclosed in U.S. Pat. No.
4,480,178 issued Oct. 30, 1984 to R. R. Miller II, et al for a "Tuning
Arrangement for Interfacing Credit Card-Like Device to a Reader System,"
assigned to the assignee hereof and incorporated herein by reference. The
reference discloses an arrangement that provides operating power to the
PDC through a capacitive interface. A variable inductor automatically
tunes a power transfer circuit to resonance and thereby maximizes power
transfer to the card. Unfortunately, the size of the capacitor plates
limits the amount of power that can be transferred to the card.
An improved technique for transferring power to the PDC is disclosed in
U.S. Pat. No. 4,692,604 issued Sept. 8, 1987 to Billings for a "Flexible
Inductor," assigned to the assignee hereof and incorporated herein by
reference. This application discloses a card having a flexible coil and a
flexible ferromagnetic member which, when inserted into an associated card
reader/writer unit, inductively couples to a transformer primary so that
the coil in the PDC operates as a transformer secondary and, in that role,
receives electrical power from the reader/writer unit. No provision,
however, is made in such an arrangement to regulate the amount of power
that is delivered to the card. The proper positioning of the PDC in the
reader/writer unit is of some significance in this regard; equipment
tolerances and variation in air gaps among different PDCs may cause too
little or too much power to be transferred to the card. Too little power
would not activate the circuitry while too much power would damage it.
Another general concern is the need to determine whether a conventional
credit card or a PDC is being inserted into the reader/writer unit without
requiring the card holder to enter such information.
Accordingly, it is an object of the present invention to provide a card
reader/writer unit with the ability to distinguish the type of card
(conventional or PDC) that is inserted therein.
It is another object of the invention to transfer a predetermined amount of
power to a PDC, inserted into a card reader/writer unit, regardless of
card warpage or improper alignment between the card and the unit.
SUMMARY OF THE INVENTION
A power transfer arrangement is disclosed for magnetically coupling a
predetermined amount of electrical power to a load impedance contained on
a Personal Data Card (PDC). A power amplifier, driven by an oscillator,
includes a variable voltage source and a first coil that operates as a
transformer primary - the transformer secondary being another coil located
on the PDC. The arrangement is characterized by apparatus for measuring
the magnitude of current flow through the first coil and the magnitude of
the variable voltage source. The product of these magnitudes forms a
measure of generated power. Apparatus is provided for storing the measured
power and for detecting the presence or absence of a card so that power
might be measured both with and without the load impedance present.
Apparatus is also provided for calculating the difference between the
power with and without the load impedance present, and for varying the
magnitude of the variable voltage source until the power difference is
substantially equal to the predetermined amount of electrical power.
It is a feature of the present invention that regulated power may be
supplied to a PDC with minimum power dissipation on the PDC itself.
It is another feature of the present invention that the oscillator used in
connection with power transfer also provides timing to the PDC.
BRIEF DESCRIPTION OF THE DRAWING
The invention and its mode of operation will be more readily understood
from the following detailed description when considered in connection with
the accompanying drawings in which:
FIG.1 illustrates, in block diagram form, a regulated power delivery system
for a contactless data card in accordance with the invention;
FIG. 2 discloses schematic details of the regulated power delivery system
generally illustrated in FIG. 1; and
FIGS. 3 and 4 depict a flow chart that illustrates the particular
operations performed by a microprocessor to implement the invention.
DETAILED DESCRIPTION
FIG. 1 generally illustrates, in block diagram form, a power delivery
system for an electronic transaction card, also referred to as a Personal
Data Card (PDC). PDC 200 is intended to be inserted into a card
reader/writer unit (receptor) designed to transfer data to and receive
data from the PDC by way of electrical signals. PDC 200 is similar in
appearance to a conventional credit card in that it is made from an opaque
plastic material and is of approximately the same dimensions
(85.7.times.54.times.0.76 mm). PDC 200 further includes the full power of
a microprocessor and associated memory--integrated circuits that are
embedded within the plastic of the card and require power in order to
operate. Although a number of techniques exist for providing power to such
circuits, the present invention discloses an apparatus and method for
delivering only a predetermined amount across a contactless interface.
FIG. 1 focuses on the power transfer from the reader/writer unit to the
PDC. Aspects such as data transfer between the PDC and the reader/writer
unit are not discussed herein.
PDC 200 includes a number of circuits that require power in order to
operate and are collectively represented by block 220. Inductive device
201 includes a flexible coil and a flexible core piece. This inductive
device forms a secondary coil of a transformer which cooperates with
primary coil 101 located in power delivery system 100 of the reader/writer
unit. Rectifier 210 operates to convert AC voltage into DC voltage; such
rectifiers are well known among those skilled in the art. Reference clock
230 extracts timing from the AC voltage delivered to inductive device 201
and generates a clock signal for use by the circuits designated 220.
The portion of the reader/writer unit that operates to power the PDC
comprises power delivery system 100 and power regulator 300. Power
amplification circuit 130 is driven by oscillator 110 and in turn drives
primary coil 101. Voltage is supplied to primary coil 101 in a center
tapped arrangement fed from variable voltage source 320. Current monitor
120 measures the DC current drive that flows through primary coil 101.
Processor 310, among other things, controls the primary voltage level,
V.sub.p, applied to the center tap of primary coil 101 and stores in its
memory the DC current drive measured by current monitor 120.
Before PDC 200 is inserted into the reader/writer unit, processor 310
causes variable voltage source 320 to apply a sequence of stepped voltage
levels to primary coil 101 and store in its memory the measure of a
quiescent DC current drive associated with each of the stepped voltage
levels. After PDC 200 is inserted into the reader/writer module, processor
310 causes variable voltage source 320 to increase the voltage applied to
primary coil 101 in a similar sequence of stepped voltage levels.
Thereafter, current monitor 120 measures the DC current drive through
primary coil 101 and presents that measurement, in digital form, to
processor 310 where it is stored in association with the particular
primary voltage that caused it to flow. A measure of power is then
calculated from the product of these currents and voltages. For each of
the stepped voltages a power difference is also calculated between the
measured power with and without the PDC inserted. This power difference
corresponds to the amount of power actually delivered to the PDC. When
this amount exceeds a predetermined threshold the stepping process is
discontinued, and the voltage presently being applied to primary coil 101
is fixed until the PDC is removed from the reader/writer unit. After
removal of the PDC, new quiescent values of power are calculated.
Referring now to FIG. 2, oscillator 110 supplies a 1.8432 MHz square wave
to transformer 137 through a preamplifier comprising components 131-136.
In the preamplifier, resistor 132 provides bias stabilization and sets the
emitter current while capacitor 133 is an associated AC bypass. The
preamplifier's square wave output is converted into a sine wave by the
primary of interstage transformer 137 which is resonated by the input
capacitance of the drive FETs, reflected back to transformer 137, and
capacitor 136 in parallel with the transformer primary. Resistor 135
provides a fixed output impedance that prevents shorting of the tank
circuit (from an AC standpoint) when transistor 134 is on. Transformer 137
is designed to step up the voltage by a factor of four and it is center
tapped to split the output into two signals--180 degrees apart.
The drive circuit of the power amplifier consists of two FETs, 141-142,
arranged as a push-pull, class B amplifier. Tuning capacitors 144, 145 and
resistors 143, 146 and 123 are used for wave shaping. The push-pull
configuration is used to obtain a larger peak-to-peakoutput swing from the
fixed supply than would be possible with a single device amplifier.
Theoretically, a peak-to-peak swing of four times the supply voltage can
be obtained when the output coil is resonated. Obtaining this output swing
is important because it allows the primary to have more turns for the same
voltage output at the secondary. This in turn lowers circuit Q, and
consequently circuit losses. The peak swing on each FET gate can be as
high as 18 volts in the present circuit. This swing is intentionally made
high to insure that all devices will turn on hard, thus reducing the
variation of "on" channel resistance that might be encountered over
various devices if a low drive level is used.
FETs 141, 142 have a V.sub.t of 2 to 4 volts, and an "on" channel
resistance of 2.4 ohms max. The gate drives are provided by a center
tapped transformer output, from the predrive, with the center tap DC
biased at 1.8 volts nominally to reduce deadband during transition
intervals. A voltage divider comprising resistors 138, 140 along with
filter capacitor 139 provides the necessary bias.
Capacitors 144, 145 are used to resonate the primary coil 101. Without
definite tuning, the primary would be excited at its self-resonant
frequency and produce severe ringing which would create the possibility of
false clock pulses appearing on the secondary. Tuning also makes the
primary circuit look like a "real" load to the drive circuit, thus greatly
reducing reactive current components in the drive and the associated
losses. The tuning capacitance is split between capacitors 144-145, each
having double the required value of capacitance and placed in series
across the primary halves. This provides a smoother and more symmetrical
output waveform than a single capacitor placed across the entire primary
coil 101.
It is important to acquire a measure of the drive current flowing though
coil 101 so that an estimate of power consumption can be made. Since all
current that passes through the coil also passes through resistor 125
located in current monitor 120, the DC voltage across resistor 125 is
proportional to the drive current. Resistor 125 serves as the drive
current sensing resistor as well as a source degeneration resistor for
drive FETs 141, 142. The voltage across resistor 125 is filtered by
resistors 122, 123 and capacitor 124. Analog to Digital (A/D) converter
121 is a device used to convert an analog voltage, present at its input,
into an ordered sequence of 8 binary voltages at its output. The analog
voltage referred to is, of course, the voltage across resistor 125 after
filtering. A clock signal of 153.6 kHz is applied to input 402 of A/D
converter 121 enabling it, in conjunction with the reference voltage on
input 401, to step through a series of successive approximations.
Processor 310 initiates the conversion process over leads designated 403.
A/D converter 121 presents its output data to processor 310 as a serial
bit stream over leads 403 with the Most Significant Bit (MSB) presented
first. A/D converter 121 is a conventional 8-bit serial converter such as
the ADC 0831 available from Texas Instruments.
Processor 310 is an 8-bit microcontroller, such as the Intel 8051, that
controls A/D converter 121 and power regulator 300 to determine if an
inserted card is a PDC, and to set the power transferred to the PDC to the
proper level. Optical detectors are used to sense when a card is present
and whether it is fully inserted into the reader/writer unit. These sensor
circuits are identical, and use a slotted optical switch with mechanically
activated interrupters. The aperture dimensions of the optical switch
(MST9230), used in the preferred embodiment of the invention, are 20 mils
wide by 60 mils high. The mechanical design insures that the aperture is
either completely blocked or completely opened when a card is inserted or
withdrawn, respectively. Each time a card is withdrawn from the card slot
(denoted by the return of the "card in" sensor to a high state) processor
310 enables counter 320 and sends a sequence of 15 pulses to the counter
to increment the primary voltage to maximum. The drive current that flows
in primary coil 101 is measured by A/D converter 121. Processor 310 then
stores the value of quiescent drive current for each step of primary
voltage; quiescent power being measured when no card is inserted in the
reader/writer unit.
When the card trips the "card fully inserted" sensor, a measurement of
maximum current flow in primary coil 101 is made. Processor 310 then
compares this current flow with the stored value of current flow in the
primary coil without the card inserted. If the difference is greater than
a predetermined threshold, then the card is considered to be a PDC and a
clamp is activated to hold the PDC in place. The predetermined threshold
is a variable, stored in memory, that can be assigned any value.
Before clamping the PDC, processor 310 transmits one more pulse to counter
321 which rolls it over to zero and sets the primary voltage to minimum.
After the card is clamped, processor 310 measures the active current
(I.sub.a,n) flowing in the primary coil. The value of quiescent drive
current (I.sub.q,n) for that value of primary voltage is recalled from
memory and subtracted from the value obtained with the card clamped. This
change in current is multiplied by the primary voltage and by a correction
factor, whose values are stored in ROM, to determine the power being
delivered to the PDC. If the calculated card power is below a
predetermined threshold (200 mW for example), then the processor
increments the primary voltage, measures the drive current, repeats the
calculations, and again checks for proper level in the card. Once the
power being drawn by the card exceeds the predetermined threshold,
processor 310 holds the primary voltage at that value until the card is
removed; thereafter, processor 310 re-measures and stores the quiescent
drive current at all primary voltage levels.
Counter 321 accepts pulses from processor 310 over lines 406 to generate a
parallel binary output signal on lines 407. An acceptable device is a
4-bit binary counter, such as the 74LS93, that generates sixteen different
states. Quad comparator 322 compares binary signals present on lines 407
to reference voltages on lines 408 to drive four "open collector"
transistor circuits at its output. These output signals generally operate
as switches between resistors 323-326 and ground. A suitable device is the
LM339 which is available from a number of manufacturers. A sequence of
sixteen different voltages are thus presented to the inverting input of
amplifier 330 and compared with a reference voltage present on its
non-inverting input. The reference voltage is formed by a well-known
configuration comprising series dropping resistor 501, Zener diode 502,
and filtering capacitor 503. A value of 1.235 volts is used in the
preferred embodiment. The various voltage levels emanating from amplifier
330 ultimately control primary voltage V.sub.p on lead 409 via pass
transistor 335. In the preferred embodiment, the regulator is set to step
from 6.75 to 10.5 v in equal increments. Resistor 328 provides negative
feedback to amplifier 330 and maintains bias stability. Since primary
voltage V.sub.p is supplied to the preamplifier as well as the power
amplifier, the effect of variations in V.sub.p are multiplied. Capacitor
337 provides filtering for V.sub.p.
Referring now to the flow chart of FIGS. 3 and 4, steps are set forth that
provide the basis for a simple computer program to perform all necessary
tasks of processor 310 in controlling power delivered to the PDC in
accordance with the invention. Initialization sequence 600 is desi9ned to
establish a table of quiescent currents that flow in primary coil 101 when
the PDC is not inserted in the reader/writer unit.
Step 601 sets n=0. This value of n is thereafter used by the 4-bit binary
counter 321 to produce parallel binary digits "0000" at its output and
ultimately provide the minimum primary voltage level--previously selected
to be 6.75 volts in the preferred embodiment. Step 602 is the current
measurement step in which A/D converter 121 provides a measure of the
quiescent current flow associated with a particular value of n and is
designated I.sub.q,n.
Steps 603 and 604 set up a loop whereby 16 total values of quiescent
current (I.sub.q,0 . . . I.sub.q,15) are measured and stored in a RAM.
Once a card is fully inserted, as indicated by a sensor on the
reader/writer unit, a maximum active current is measured (i.e., the
current that flows in primary coil 101 when V.sub.p is at its maximum
level). Steps 605 and 606 perform this task. Step 607 calculates the
current delivered to the card (I.sub.d) as the difference between the
maximum active current (I.sub.a,15) and the maximum quiescent current
(I.sub.q,15). If this delivered current (I.sub.d) exceeds reference
current (I.sub.ref), stored in memory, then it is assumed that the
inserted card is a PDC; otherwise, a magnetic stripe card (that does not
draw current) is assumed. Step 608 defines the measurement, and steps 610,
611 are self explanatory.
Step 609 is invoked when it is determined that the inserted card is a
PDC--based on the delivered current calculation. The reader/writer unit
may be equipped with a solenoid that clamps the PDC in place. Step 609
causes this to occur and simultaneously sets n=0 so that active current
measurements for various primary voltages, can be commenced. Step 612
measures and stores the value of drive current (I.sub.a,n) that flows in
primary coil 101 for each value of n.
Step 613 calculates the power that is actually delivered to the PDC, for
each new value of n, as the product of the difference currents indicated
and a voltage V.sub.n, stored in ROM. This product is then multipled by a
correction factor C.F. that is experimentally determined, stored in
memory, and used to achieve correspondence between mathematical
calculations and actual power measurements. The correction factor is a
system constant that accounts for inherent measurement inaccuracies, flux
leakage, etc.
When the power delivered to the PDC exceeds a predetermined threshold,
stored in ROM, steps 615-616 provide an indication that data transfer
between the reader/writer unit and the PDC may commence until the card is
removed. If, however, the power delivered to the PDC is less than the
predetermined threshold, step 617 increases the value of n, hence the
primary voltage, and repeats the measurements of steps 612 and 613.
In the event that the power being delivered to the PDC is still less than
the predetermined threshold after the maximum primary voltage is applied,
steps 618 and 619 provide a default state whereby a magnetic stripe card
is assumed. Normally, step 610 would have detected this condition.
When the card is removed, initialization sequence 600 is repeated to
accommodate any drift in quiescent currents from day to day due to
equipment wear, temperature variation, and unforeseen changes.
The above-described invention thus provides a method and apparatus for
delivering a predetermined amount of power to a PDC. Advantageously, power
regulation is accomplished within the card reader/writer unit so that
regulator circuits and their associated power dissipation are eliminated
from the PDC itself. As an added advantage, monitoring the amount of power
transferred provides an ability to distinguish between various types of
cards (e.g., PDC or conventional credit cards). This is useful in two
ways: (i) it provides an ability to be compatible with conventional credit
cards and (ii) it provides a means for distinguishing among future "smart
cards."
Although power regulation is well known, the present invention provides a
unique way in which to achieve it across a contactless interface; and
while a specific embodiment is disclosed, it is understood that various
modifications are possible within the spirit and scope of the invention.
One modification being the elimination of quiescent current measurements
each time a card is removed from the reader/writer unit. Instead,
estimates of quiescent current are stored in memory that have been
selected as representative of the particular reader/writer unit design.
Another modification being the elimination of the microprocessor and
digital memory. Instead, an analog feedback circuit, responsive to current
flow in the primary coil, is used to control the variable voltage source.
System parameters that are expected to exhibit minimum variation over the
lifetime of the reader/writer unit, such as quiescent currents, are
accommodated by adjustable components in the feedback circuit that are
fixed at the time of manufacture.
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