U.S. patent application number 15/016601 was filed with the patent office on 2016-08-18 for method for facilitating payment with a reprogrammable payment card.
The applicant listed for this patent is Stratos Technologies, Inc.. Invention is credited to Henry Balanon, Christopher Bartenstein, Thiago Olson.
Application Number | 20160239829 15/016601 |
Document ID | / |
Family ID | 53368898 |
Filed Date | 2016-08-18 |
United States Patent
Application |
20160239829 |
Kind Code |
A1 |
Olson; Thiago ; et
al. |
August 18, 2016 |
METHOD FOR FACILITATING PAYMENT WITH A REPROGRAMMABLE PAYMENT
CARD
Abstract
One variation of a method for facilitating payment with a
payment card includes: in response to an input on the surface of
the payment card exceeding a first input threshold magnitude,
transitioning from the off state into a primary payment mode; in
the primary payment mode, activating a first timer of a first
duration; in response to expiration of the first timer prior to a
magnetic read head proximal the payment card, transitioning from
the primary payment mode into a sleep state; in response to an
input on the surface of the payment card exceeding a second input
threshold in the sleep state, transitioning into a secondary
payment mode; in the secondary payment mode, activating a second
timer of a second duration less than the first duration; and
driving a magnetic stripe emulator within the payment card
according to a magnetic sequence command corresponding to a
magnetic stripe card.
Inventors: |
Olson; Thiago; (Ann Arbor,
MI) ; Bartenstein; Christopher; (Ann Arbor, MI)
; Balanon; Henry; (Ann Arbor, MI) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Stratos Technologies, Inc. |
Ann Arbor |
MI |
US |
|
|
Family ID: |
53368898 |
Appl. No.: |
15/016601 |
Filed: |
February 5, 2016 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
14542245 |
Nov 14, 2014 |
9275386 |
|
|
15016601 |
|
|
|
|
62003446 |
May 27, 2014 |
|
|
|
61962709 |
Nov 14, 2013 |
|
|
|
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G06Q 20/354 20130101;
G06K 19/06196 20130101; G06Q 20/341 20130101 |
International
Class: |
G06Q 20/34 20060101
G06Q020/34; G06K 19/06 20060101 G06K019/06 |
Claims
1. A method for facilitating payment with a payment card
comprising: at the payment card, in response to detecting an input
on a surface of the payment card exceeding a first input threshold
magnitude, transitioning from an off state into a primary payment
mode; in the primary payment mode, activating a first timer of a
first duration; following detecting a magnetic read head proximal
the payment card prior to expiration of the first timer,
transitioning from the primary payment mode into the off state; in
response to expiration of the first timer prior to detecting a
magnetic read head proximal the payment card, transitioning from
the primary payment mode into a sleep state; in response to
detecting an input on the surface of the payment card exceeding a
second input threshold magnitude less than the first input
threshold magnitude in the sleep state, transitioning from the
sleep state into a secondary payment mode; in response to entering
the secondary payment mode, activating a second timer of a second
duration less than the first duration; following detecting a
magnetic read head proximal the payment card prior to expiration of
the second timer, transitioning from the secondary payment mode
into the off state; in response to expiration of the second timer
prior to detecting a magnetic read head proximal the payment card,
transitioning from the secondary payment mode into the sleep state;
and in the primary payment mode and in the secondary payment mode,
in response to detecting a magnetic read head proximal the payment
card, driving a magnetic stripe emulator within the payment card
according to a magnetic sequence command stored on the payment card
and corresponding to a magnetic stripe card.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This Application is a continuation of U.S. patent
application Ser. No. 14/542,245 filed 14 Nov. 2014, which claims
the benefit of U.S. Provisional Patent Application No. 61/962,709,
filed on 14 Nov. 2013, and U.S. Provisional Patent Application No.
62/003,446, filed on 27 May 2014, both of which are incorporated in
their entireties by this reference.
[0002] Furthermore, this Application is related to U.S. patent
application Ser. No. 13/904,939, filed on 29 May 2013, which is
incorporated in its entirety by this reference.
TECHNICAL FIELD
[0003] This invention relates generally to the field of bank cards
and, more specifically, to a new and useful for facilitating
payment with a reprogrammable payment card in the field of bank
cards.
BRIEF DESCRIPTION OF THE FIGURES
[0004] FIG. 1 is a flowchart representation of a method of the
invention; and
[0005] FIGS. 2A, 2B, and 2C are schematic representations of a
payment card in accordance with the method;
[0006] FIG. 3 is a graphical representation in accordance with the
first method and the second method;
[0007] FIG. 4 is a flowchart representation in accordance with one
variation of the method;
[0008] FIG. 5 is a flowchart representation in accordance with one
variation of the method; and
[0009] FIG. 6 is a flowchart representation in accordance with one
variation of the method.
DESCRIPTION OF THE EMBODIMENTS
[0010] The following description of the embodiments of the
invention is not intended to limit the invention to these
embodiments, but rather to enable any person skilled in the art to
make and use this invention.
1. Method
[0011] As shown in FIG. 1, a method for facilitating payment with a
payment card includes: at the payment card, in response to
detecting an input on a surface of the payment card exceeding a
first input threshold magnitude, transitioning from an off state
into a primary payment mode in Block S110; in the primary payment
mode, activating a first timer of a first duration in Block S120;
in response to detecting a magnetic read head proximal the payment
card prior to expiration of the first timer, transitioning from the
primary payment mode into the off state in Block S130; in response
to expiration of the first timer prior to detecting a magnetic read
head proximal the payment card, transitioning from the primary
payment mode into a sleep state in Block S140; in response to
detecting an input on the surface of the payment card exceeding a
second input threshold magnitude less than the first input
threshold magnitude in the sleep state, transitioning from the
sleep state into a secondary payment mode in Block S150; in
response to entering the secondary payment mode, activating a
second timer of a second duration less than the first duration in
Block S160; following detecting a magnetic read head proximal the
payment card prior to expiration of the second timer, transitioning
from the secondary payment mode into the off state in Block S110;
in response to expiration of the second timer prior to detecting a
magnetic read head proximal the payment card, transitioning from
the secondary payment mode into the sleep state in Block S180; and
in the primary payment mode and in the secondary payment mode,
following detecting a magnetic read head proximal the payment card,
driving a magnetic stripe emulator within the payment card
according to a magnetic sequence command stored on the payment card
and corresponding to a magnetic stripe card in Block S190.
[0012] As shown in FIGS. 1 and 5, one variation of the method
includes: at the payment card, in an off state, applying a first
input threshold magnitude for detecting an input on a surface of
the payment card in Block S102; in response to detecting an input
on the surface of the payment card exceeding a first input
threshold magnitude, transitioning from the off state into a
primary payment mode in Block S110; in the primary payment mode,
activating a first timer of a first duration in Block S120; in
response to expiration of the first timer prior to detecting a
magnetic read head proximal the payment card, transitioning from
the primary payment mode into a sleep state in Block S140; in the
sleep state, applying a second input threshold magnitude for
detecting an input on the surface of the payment card, the second
input threshold magnitude less than the first input threshold
magnitude in Block S104; in response to detecting an input on the
surface of the payment card exceeding the second input threshold
magnitude in the sleep state, transitioning from the sleep state
into a secondary payment mode in Block S150; in the secondary
payment mode, activating a second timer of a second duration less
than the first duration in Block S160; in the secondary payment
mode, following detecting a magnetic read head proximal the payment
card prior to expiration of the second timer, driving a magnetic
stripe emulator within the payment card during an emulation cycle
according to a magnetic sequence command stored on the payment card
and corresponding to a static magnetic stripe card in Block S190;
and in response completion of the emulation cycle, transitioning
from the secondary payment mode into the off state in Block
S110.
2. Applications
[0013] Generally, the method can be implemented on a reprogrammable
payment card--such as described in U.S. patent application Ser. No.
13/904,939--to enable delayed payment with a payment method stored
on the payment card once use of the payment card is authenticated
or authorized. In particular, the payment card can store one or
more payment methods in the form of magnetic sequence commands
executable by a magnetic stripe emulator to mimic static magnetic
stripes within plastic credit, debit, gift, and/or other payment
cards when the reprogrammable payment card is swept passed a card
reader (e.g., a magnetic read head), as shown in FIGS. 1 and 3. The
payment card can also store magnetic sequence commands
corresponding to static magnetic stripes of other card types, such
as magnetic-stripe-based door access cards, personal identification
cards, or rewards cards. A particular payment method, door code,
personal information, etc.--stored in the form of a magnetic
sequence command on the payment card--can thus be selected for an
upcoming transaction between the payment card and a magnetic read
head, and the payment card can thus emulate the selected payment
method, door code, or personal information by driving the magnetic
stripe emulator, arranged within the payment card, according to the
corresponding magnetic sequence command.
[0014] However, because such a reprogrammable payment card may
require power to repeatedly probe for a nearby card reader to
trigger powered emulation of a static magnetic stripe at the
magnetic stripe emulator contained therein, repeated long delays
between activation of the payment card and use of the payment card
in a subsequent transaction may relatively quickly consume power
from a battery within the payment card, thereby negativing a useful
life of the payment card. For example, once a transaction with the
payment card is authorized and the payment card armed to emulate a
selected payment method, the payment card can arm the magnetic
stripe emulator within the payment card, sample a magnetic read
head sensor until a magnetic read head is detected adjacent the
payment card, and trigger the magnetic stripe emulator to emulate
the selected payment method once a magnetic read head is detected;
however, longer time durations between activation of the payment
card and emulation of a payment method can drain charge from a
battery contained within the payment card, thereby reducing the
life of the payment card for the battery that is not rechargeable
or requiring recharge sooner for the battery that is rechargeable.
Therefore, the payment card can implement the method to handle
transitions between an off state, a primary payment mode, a
secondary payment mode, and a sleep state. Accordingly, the payment
card can thus operate in a relatively low(est) power setting and at
a first sensitivity to an input on its surface in the off state,
can sample a magnetic read head sensor to detect an adjacent
magnetic read head and can be armed to emulate a selected payment
method for a first period of time (e.g., ninety seconds) in the
primary payment mode, can operate in a relatively low(est) power
setting but at a heightened sensitivity to an input on its surface
in the sleep state, and can sample the magnetic read head sensor
for an adjacent magnetic read head and can be armed to emulate a
selected payment method for a more limited period of time (e.g.,
500 microseconds) in the secondary payment mode.
[0015] In one example application of the payment card executing the
method, an owner of the payment card (i.e., the "user") enters a
bar early one evening, orders a cocktail containing bourbon, sweet
vermouth, and a cherry, removes the reprogrammable payment card
from his wallet, taps the payment card to trigger the payment card
to enter the primary payment mode, selects a payment method (or
leaves a default payment method in place) at the payment card, and
hands the payment card to a barkeeper; the barkeeper stores the
payment card behind the bar until the user is ready to close his
tab. A first timer for ninety seconds was initiated at the payment
card once the payment method was selected; ninety seconds later,
the first timer on the payment card expires and the payment card
transitions into the sleep state because the payment card was not
swept passed a card reader before expiration of the first timer
(i.e., because the magnetic read head sensor in the payment card
did not detect a magnetic read head adjacent the payment card
before expiration of the first timer). As the evening progresses,
the user orders several more cocktails, and the payment card
remains with the barkeeper as the user runs up his tab on
overpriced, under-alcoholed San Francisco cocktails. Soon after the
barkeeper shouts last call, the user wearily indicates his wish to
retire, and the barkeep retrieves the user's payment card. When the
barkeeper handles the payment card, slight deflection of the
payment card wakes an internal processor within the payment card,
thereby triggering the payment card to enter the secondary payment
mode. Once in the secondary payment mode, the payment card
initiates a second timer for 1200 milliseconds. However, the
barkeep takes his time selecting the correct tab for the user, and
the payment card returns to the sleep state upon expiration of the
second timer because no magnetic read head was detected by the
magnetic read head sensor within the payment card. Finally, the
barkeeper begins to swipe the payment card through a card reader,
and deflection of the payment card by handling again wakes the
processor into the secondary payment mode, and the magnetic read
head sensor detects the card reader adjacent the payment card,
thereby triggering the processor to drive the magnetic stripe
emulator according to the payment method--selected earlier in the
evening by the user--as the payment card is swept through the card
reader by the barkeeper. Once the magnetic stripe emulator
completes the magnetic sequence command for the selected payment
method, the payment card transitions back into the off state, the
barkeeper returns the payment card to the user, and the user
stumbles home.
3. Payment Card
[0016] As described in U.S. patent application Ser. No. 13/904,939
and shown in FIGS. 2A, 2B, and 2C, the payment card can include: a
sheet 110 including a first icon in and a second icon 112; a
transducer 150 arranged within the sheet 110 and configured to
output a voltage in response to an impulse on a surface of the
sheet 110; a wireless communication module 120; a first input
region 131 adjacent the first icon 111; a second input region 132
adjacent the second icon 112; a magnetic stripe emulator 140; a
magnetic read head sensor configured to detect a magnetic read head
proximal the payment card; and a processor 160 arranged within the
sheet no and configured to transition from a passive state (e.g.,
the off state, the sleep state) into an active state (e.g., the
primary payment mode, the secondary payment mode) in response to
receiving a voltage output from the transducer 150, to receive a
first magnetic sequence command associated with a first payment
method and a second magnetic sequence command associated with a
second payment method through the wireless communication module
120, to assign the first payment method to the first input region
131 and the second payment method to the second input region 132,
to receive a selection for the second payment method from the
second input region 132 in response to an input adjacent the second
icon 112, and to control the magnetic stripe emulator 140 according
to the second magnetic sequence command in response to receiving
the selection for the second payment method.
[0017] Generally, the payment card functions to consolidate
multiple plastic payment cards into a single physical card that can
imitate payment functionalities of the multiple plastic payment
cards through manipulation of a magnetic stripe emulator. For
example, the payment card can imitate a user's debit card issued
through a bank, a user's primary credit card issued by a preferred
credit card company, and a user's secondary credit card issued by
another credit card company by selectively driving the magnetic
stripe emulator according to a unique magnetic sequence command
associated with each individual card. The payment card can
additionally or alternatively imitate a gift card, an
identification (i.e., ID) card (e.g., a driver's license), a
loyalty card, a door or gate access card, or any other individual
card containing data in a magnetic stripe. The payment card can
define a form factor substantially similar to that of a standard
plastic payment card, that is, 3.370'' (850.60 mm) wide by 2.125''
(53.98 mm) tall by 0.6'' thick.
[0018] The payment card can thus include multiple "payment slots,"
each holding data (e.g., a magnetic stripe sequence command)
pertaining to a particular payment method loaded onto the payment
card. For example, a "first payment slot" on the payment card can
"hold" (e.g., point to) credit card data, a "second payment slot"
on the payment card can hold debit card data, and a "third payment
slot" on the payment card can hold gift card data; a user can thus
select one of the first, second, and third slots to arm the
magnetic stripe emulator (or the processor) within the payment card
with the corresponding payment method. Subsequently, the payment
card can drive the magnetic strip emulator according to a magnetic
stripe sequence corresponding to the payment method in the selected
payment slot to enable a transaction with the payment method when
the payment card is swept passed a card reader (e.g., a magnetic
read head). The payment card can also interface with a mobile
computing device to upload new payment method data to payment slots
on the payment card, to delete payment method data from the payment
card, to control payment card functions asynchronously or in
real-time, to authenticate an upcoming transaction, etc.
4. Off State to Primary Payment Mode
[0019] Block S110 of the method recites, at the payment card, in
response to detecting an input on a surface of the payment card
exceeding a first input threshold magnitude, transitioning from an
off state into a primary payment mode. Generally, Block S110
functions to transition the payment card from an "off state" into a
"primary payment mode" in response to an input on the payment card
by a user, such as in preparation for use of the payment card in an
upcoming transaction. In particular, the payment card can operate
in a relatively lowest-power setting in the off state, such as by
ceasing operation of an internal wireless communication module and
disabling sensing routines at an internal processor for internal
magnetic read head sensor(s) and input (e.g., capacitive touch)
sensors correspond to payment slots on the payment card. The
payment card can further transition into a higher-power setting in
the primary payment mode, wherein operation of the wireless
communication module is enabled to establish a wireless connection
between the payment card and a wirelessly-paired mobile computing
device, wherein the processor polls the magnetic read head
sensor(s) to detect an magnetic read head adjacent the payment
card, and wherein the processor polls the input sensors to detect a
selection for a payment method for an upcoming transaction at the
payment card.
[0020] In one implementation and as described in U.S. patent
application Ser. No. 13/904,939, the processor within the payment
card implements Block S110 by interfacing with a piezoelectric
transducer electrically coupled to a first `wake` interrupt-enabled
input pin of the processor. In this implementation, when a user
taps on, bends, or otherwise handles the payment card with
sufficient force, the piezoelectric transducer outputs an
electrical signal--exceeding a threshold voltage set at the first
interrupt-enabled pin--to the first interrupt-enabled pin of the
processor, and the processor wakes from the off state and
transitions into the primary payment mode accordingly. Generally, a
voltage output of the piezoelectric transducer can be proportional
to a maximum degree of deflection of the piezoelectric transducer
and/or to a degree of deflection of the piezoelectric transducer
over a period of time (e.g., a rate of deflection). The processor
can also be configured to trigger an interrupt when a voltage at
the first interrupt-enabled input pin--electrically coupled to the
piezoelectric transducer--exceeds a first threshold voltage (e.g.,
2.2V for a 3.3V CMOS logic processor, 2V for a 5V TTL logic
processor). Alternatively, the first interrupt-enabled input pin of
the processor can be coupled to the piezoelectric transducer via a
signal conditioning circuit--such as including a Zener diode or a
comparator operation amplifier (op amp)--that outputs a voltage to
the first interrupt-enabled input pin of the processor to trigger
an interrupt at the processor when a voltage output of the
piezoelectric transducer exceeds the first threshold voltage (i.e.,
a first input threshold magnitude) set or defined by the signal
conditioning circuit (e.g., 2.5 V for a Zener diode). In
particular, the piezoelectric transducer can output a signal of
magnitude value (e.g., peak voltage) exceeding the first input
threshold magnitude--coded into the first interrupt-enabled input
pin of the processor or defined by the signal conditioning
circuit--in response to an input on the surface of the payment card
that bends or deflects the surface out of plane by at least a first
degree; and the processor can implement Block S110 to transition
from the off state into the primary payment mode in response to a
magnitude value (e.g., peak voltage) of a signal output from the
piezoelectric transducer exceeding the first input threshold
magnitude.
[0021] Alternatively, a motion sensor (e.g., an accelerometer, a
tilt sensor, a gyroscope) can be electrically coupled to the first
interrupt pin of the processor, and the processor can implement
Block S110 to transition from the off state into the primary
payment mode when a user taps on, bends, or moves (e.g., jostles)
the payment card with sufficient vigor that the motion sensor
outputs an electrical signal--exceeding the first input threshold
magnitude--to the first interrupt pin of the processor. For
example, in the off state, the processor can sample an
accelerometer within the payment card at a first sampling rate
(e.g., 1 Hz), compare a form of an output of the accelerometer
(e.g., a digital form of an analog voltage output of the
accelerometer) to the first input threshold magnitude (e.g.,
voltage threshold), and transition the payment card from the off
state into the primary payment mode in response to the form of the
output of the accelerometer exceeding the first input threshold
magnitude, such as if accelerations along three Cartesian axes of
the payment card from an input on the payment card yields a
composite voltage output from the accelerometer that exceeds a
threshold composite voltage at the first interrupt-enabled pin of
the processor. Therefore, in this example, the processor can
interface with an accelerometer within the payment card to
transition from the off state into the primary payment mode when an
impact on the payment card yields a detected acceleration exceeding
a threshold acceleration; the processor can implement Block S110 by
converting a voltage output from the accelerometer into a digital
value and comparing this digital value to a threshold digital value
to determine if the impact on the payment card is sufficient to
wake the payment card from the off state into the primary payment
mode.
[0022] Yet alternatively, in another implementation, the payment
card can implement Block S110 to trigger entry into the primary
payment mode in response to selection of an input region on the
payment card. For example, an input region on the payment card can
be electrically coupled to a first interrupt-enabled pin of the
processor, and the input region can communicate a digital low
voltage value to the first interrupt-enabled pin of the processor
in a steady state and can communicate a digital high voltage value
to the first interrupt-enabled pin of the processor when depressed
(or vice versa); the processor can thus transition from the off
state into the primary payment mode when the voltage across the
first interrupt-enabled pin changes from a digital low voltage
(e.g., .about.0V) to a digital high voltage (e.g., .about.3.3V).
Similarly, the processor can implement Block S110 to trigger entry
into the primary payment mode in response to entry of a first
sequence of inputs onto one or more regions of the payment card,
such as a sequence of inputs onto each of three input
regions--corresponding to payment slots on the payment card--in the
form of a passcode.
[0023] However, the payment card can implement Block S110 to handle
any other type of input or sequence of inputs on the payment card
to trigger the payment card (e.g., the processor within the payment
card) to transition from the off state into the primary payment
mode.
5. Authentication
[0024] As shown in FIGS. 1 and 4, one variation of the method
includes Block S112, which recites, in response to entering the
primary payment mode, authenticating a future transaction with the
magnetic sequence command. Generally, Block S112 functions to
authenticate use of the payment card for a subsequent transaction
once the payment card enters the primary payment mode.
[0025] In one implementation and as described in U.S. patent
application Ser. No. 13/904,939, the processor executes Block S112
by attempting--through the wireless communication module--to
establish a wireless connection with a computing device affiliated
with the payment card. For example, a unique wireless address
corresponding to a mobile computing device (e.g., a smartphone)
associated with the payment card can be stored in memory on the
payment card, such as in local memory on the wireless communication
module. In this example, in response to transition from the off
state into the primary payment mode, the processor can trigger the
wireless communication module to attempt to pair wirelessly (e.g.,
over Bluetooth) with a local mobile computing device assigned the
unique wireless address. If a mobile computing device with the
unique wireless address is found and a wireless connection with the
mobile computing device successfully established, the processor can
authorize use of the payment card in a subsequent transaction. The
processor can then execute Block S114, as described below, to arm a
controller within the payment card to drive the magnetic stripe
emulator according to a default magnetic stripe sequence command in
response to authorization of use of the payment card.
Alternatively, the processor can then execute Block S116, as
described below, to receive a manual selection for a particular
payment method (or other magnetic stripe card) for emulation in the
upcoming transaction, and the processor can thus arm a controller
within the payment card to drive the magnetic stripe emulator
according to a corresponding magnetic stripe sequence command.
[0026] Thus, in the foregoing implementation, if the payment card
succeeds in establishing a wireless connection with a particular
(e.g., paired) mobile computing device, the processor can confirm
that the payment card is sufficiently near (e.g., within a
threshold authentication range of) the mobile computing device,
which may indicate that an owner of the mobile computing
device--who is also an owner of the payment card--is within a
suitable proximity to the payment card. The processor can thus
execute Block S112 to authenticate use of the payment card in a
subsequent transaction.
[0027] However, in this implementation, if the wireless
communication module fails to establish a wireless connection with
the particular mobile computing device, the processor can prompt
the user to enter a passcode as a backup authentication method in
Block S112. For example, the processor can trigger a visual
indicator (e.g., an LED lamp) within the payment card to signal to
the user failure to authenticate use of the payment card (e.g., by
flashing the LED lamp) though wireless communication with the
affiliated mobile computing device and to thus prompt the user to
enter a passcode into the payment card to manually authenticate use
of the payment card. In this implementation, the processor can
sample (e.g., poll) one or more input regions on the payment card
to detect a sequence of inputs onto the payment card, and the
processor can authenticate use of the payment card if the sequence
of inputs matches a passcode stored on the payment card, such as
described in U.S. patent application Ser. No. 13/904,939. However,
the payment card can implement Block S112 in any other way to
authenticate use of the payment card in a subsequent
transaction--such as automatically based on proximity of the
payment card to a paired mobile computing device or based on a
passcode entered manually into the payment card--in response to
entry of the payment card into the primary payment mode.
6. Magnetic Stripe Card Selection
[0028] As shown in FIG. 1, one variation of the method includes
Block S114, which recites, in response to entering the primary
payment mode, assigning a particular payment method selected for a
preceding transaction to a default payment slot on the payment
card. Generally, Block S114 functions to set a payment method used
in a (immediately-) preceding transaction as a default payment
method for the upcoming transaction. For example, the processor
within the payment card can execute Block S110 by interfacing with
a piezoelectric transducer to detect a tap input on a surface of
the payment card and can thus transition the payment card into the
primary payment mode accordingly; the processor can then execute
Block S112 to authenticate use of the payment card and
automatically execute Block S114 to automatically select a
particular magnetic stripe sequence command--corresponding to a
particular magnetic stripe card last used at the payment card--for
the upcoming transaction. The payment card can thus implement Block
S114 to set or select a default payment method for an upcoming
transaction with the payment card based on a transaction history
with the payment card, such as in response to authenticating use of
the payment card in Block S112.
[0029] As shown in FIG. 1, one variation of the method includes
Block S116, which recites, in the first mode, at the payment card,
receiving a selection for a particular payment method from a set of
payment methods stored on the payment card and arming the payment
card to drive the magnetic stripe emulator according to a magnetic
stripe sequence command corresponding to the particular payment
method in response to the selection. Generally, Block S116
functions to receive a selection for a payment method (or other
magnetic stripe card) corresponding to a magnetic stripe sequence
command stored on the payment card and to set the payment card to
emulate the payment method based on the corresponding magnetic
stripe sequence command when the payment card is swept passed a
card reader. For example and as described in U.S. patent
application Ser. No. 13/904,939, in response to authenticating use
of the payment card in Block S112, the processor can execute Block
S116 by polling one or more input regions on the payment card for
an input, correlating the input with a selection for a particular
payment slot of the payment card, and arming the magnetic stripe
emulator to implement a particular magnetic stripe sequence command
corresponding to a magnetic stripe card assigned to the particular
payment slot.
[0030] Alternatively, once a wireless connection is established
between the payment card and a paired mobile computing device, the
payment card can execute Block S116 by receiving a payment method
selection from the mobile computing device over the wireless
connection (and a corresponding magnetic sequence command when
applicable) and preparing to drive the magnetic stripe emulator
accordingly when the payment card is swept through a card reader.
For example, multiple magnetic stripe sequence commands
corresponding to various magnetic stripe cards (e.g., credit cards,
gift cards, personal identification cards, door access cards, etc.)
can be stored in memory on the mobile computing device and accessed
through a native payment card application executing on the mobile
computing device. The native payment card application can support
an interface accessible by a user through the mobile computing
device: to select magnetic sequence commands--from the set of
magnetic sequence commands stored on the mobile computing
device--to upload to particular payment slots of the payment card
for subsequent manual selection at the payment card for the
upcoming transaction; to select a particular magnetic sequence
command--from the set of magnetic sequence commands stored on the
mobile computing device--to upload to a default or primary payment
slot on the payment card; and/or to select a particular magnetic
sequence command--stored on the payment card--for emulation by the
payment card during the subsequent transaction. Alternatively, once
a wireless connection is established between the mobile computing
device and the payment card, the native payment card application
can automatically select a particular magnetic stripe card to
emulate in the subsequent transaction--such as based on the
location of the mobile computing device--and can automatically push
the corresponding magnetic sequence command to the payment
card.
[0031] However, the payment card can implement Block S116 locally
or in cooperation with a paired mobile computing device to receive
and handle a manual (or automatic) selection for a particular
magnetic stripe card--for emulation in the subsequent
transaction--in any other suitable way.
[0032] The processor within the payment card (and/or the native
payment card application) can also select a first magnetic stripe
card to emulate if the subsequent transaction with the payment card
occurs while the payment card is in the primary payment mode and a
second magnetic stripe card to emulate if the subsequent
transaction with the payment card occurs while the payment card is
in the secondary payment mode. For example, the processor can
implement Block S116 to receive a manual selection for a debit card
for emulation during the subsequent transaction and can thus set
the debit card as a primary payment method for a subsequent
transaction; the processor can also identify a credit card
corresponding to a magnetic stripe sequence command stored on the
payment card and set this credit card as a secondary payment method
for the subsequent transaction. In this example, if the payment
card is swept through a magnetic card reader while in the primary
payment mode, the magnetic stripe emulator can thus emulate the
debit card (i.e., the primary payment method), as the user is
likely to be present to provide a personal identification number
(or "PIN") corresponding to the debit card for the transaction;
however, if the payment card is swept through a magnetic card
reader while in the secondary payment mode (after transitioning
from the primary payment mode into the sleep mode upon expiration
of the second timer), as described below, the magnetic stripe
emulator can emulate the credit card (i.e., the secondary payment
method), since the user may no longer be present to provide the PIN
for the debit card at this length of time after use of the payment
card was authenticated in Block S112, such as if the transaction
was later performed remotely from the user by a barkeeper (as in
the example above) or by a waiter at a restaurant at the close of
the user's meal. Alternatively, the native payment card application
executing on the mobile computing device can implement similar
techniques to elect a primary payment method (or magnetic stripe
card) and/or a secondary payment method (or magnetic stripe card),
and the processor can interface with the wireless communication
module to download a magnetic stripe sequence command corresponding
to the primary payment method and a magnetic stripe sequence
command corresponding to the secondary payment method from the
mobile computing device and store these in payment slots on the
payment card accordingly.
[0033] In the foregoing variation, the payment card can also select
a payment method of a first payment type (e.g., magnetic stripe)
for the primary payment method and can select a second payment
method of a second payment type (e.g., contactless NFC) (distinct
from the first payment method) for the secondary payment method.
The payment card can thus emulate one type of payment method (e.g.,
at a magnetic stripe emulator) in the primary payment method in
Block S190 and can emulate a different type of payment method
(e.g., at a NFC chip) in the secondary payment method in Block
S190.
[0034] However, the processor, payment card, and/or the native
payment card application can function in any other way to select a
primary payment method and/or a secondary payment method for use in
transaction at the payment card in the primary payment mode and the
secondary payment mode, respectively.
7. Primary Payment Mode
[0035] Block S120 of the method recites, in the primary payment
mode, activating a first timer of a first duration. Generally,
Block S120 functions to set a maximum duration of the primary
payment mode at the payment card by initiating the first timer,
such as in response to transitioning into the primary payment mode,
in response to authenticating the payment card for use (in a future
or upcoming transaction) in Block S112, and/or in response to
selection of a payment method in Block S114 or in Block S116,
etc.
[0036] In one implementation, the processor executes Block S120 by
initiating an internal timer for the first duration, such as
between one minute and two minutes. For example, in Block S120, the
processor can initiate the internal time for the first duration of
ninety seconds such that the payment card will transition out of
the primary payment mode and into the sleep state (i.e., a
lower-power state) if the payment card is not used in a transaction
within the ninety-second duration of the timer (i.e., if a magnetic
read head or other card reader is not detected near the payment
card prior to expiration of the timer), as described below;
however, if a magnetic read head (or other card reader) is detected
near the payment card while the payment card is in the primary
payment mode and before the timer expires, the processor or other
controller within the payment card can drive the magnetic stripe
emulator according to a magnetic stripe sequence command
corresponding to a magnetic stripe card selected for the
transaction, such as selected in Block S114 or Block S116. However,
the payment card can implement Block S120 to set the first timer of
any other suitable duration and to initiate the first timer in
response to any other action or event at the payment card.
Alternatively, the native payment card application executing on the
mobile computing device can initiate a timer for the first duration
locally at the mobile computing device, and the payment card can
interface with mobile computing device--via the wireless
communication module--to retrieve a state (e.g., time) of the
timer.
[0037] Block S130 of the method recites, in response to detecting a
magnetic read head proximal the payment card prior to expiration of
the first timer, transitioning from the primary payment mode into
the off state. Generally, Block S130 interfaces with one or more
magnetic read head sensors within the payment card to detect a card
reader (including a magnetic read head) adjacent the payment card
prior to expiration of the first timer, to trigger Block S190 to
drive the magnetic stripe emulator within the payment card
according to a magnetic sequence command corresponding to the
magnetic stripe card (e.g., a payment method) elected in Block S114
or Block S116, and to transition the payment card back into the off
state once emulation of the magnetic stripe card is completed.
[0038] As described in U.S. patent application Ser. No. 13/904,939,
the processor can execute Block S130 by polling one or more
magnetic read head sensors within the payment card while the first
timer is current in the primary payment mode. For example, once the
first timer is initiated in the primary payment mode, the processor
can sample the magnetic read head sensor(s) at a rate of 20 Hz
until an output of a magnetic read head sensor indicates that a
magnetic read head is proximal the payment card or until the first
timer expires. As in this example, if a magnetic read head is
detected prior to expiration of the first timer, the processor can
transition into Block S190, as described below, to drive (e.g.,
through the controller) the magnetic stripe emulator--during an
emulation cycle--according to a particular magnetic sequence
command selected for the transaction as the payment card is passed
along the magnetic read head. Once the emulation cycle is complete,
the processor can execute Block S130 by transitioning (the payment
card) from the primary payment mode into the off state. However, if
no magnetic read head (or other card reader) is detected near the
payment card prior to expiration of the first timer, the processor
can transition the payment card from the primary payment mode into
the sleep mode in Block S140, as described below.
[0039] The processor can therefore execute Blocks 130 in the
primary payment mode and while the first timer is counting down to
actively poll a magnetic read head sensor within the payment card
to detect a nearby card reader--such as as the payment card enters
into a read slot of the card reader--and to selectively execute
Block S190 to output magnetic stripe data (of a previously-selected
magnetic stripe card) to the card reader. However, the payment card
can execute Block S130 in any other way to detect a card reader
adjacent the payment card and to selectively execute Block S190 to
read payment data into the card reader while in the primary payment
mode and before expiration of the first timer.
8. Secondary Payment Mode
[0040] Block S140 of the method recites, in response to expiration
of the first timer prior to detecting a magnetic read head proximal
the payment card, transitioning from the primary payment mode into
a sleep state. Generally, Block S140 functions to transition the
payment card into a lower-power, higher-input sensitivity state
(i.e., the sleep state, as described above) if the payment card
fails to detect an adjacent card reader prior to expiration of the
first timer. In particular, by transitioning the payment card into
the sleep state in response to expiration of the first time in
Block S140, the payment card can reduce local power consumption and
thus extend battery life by limiting functions of the processor,
the wireless communication module, and/or other components within
the payment card. For example, in the sleep state, the payment card
can disable the wireless communication module, shut down all sensor
polling and processing functions of the processor, and set the
processor to respond solely to a signal of sufficient magnitude
(e.g., greater than the second input magnitude threshold), such as
a digital high signal output from a piezoelectric transducer
electrically coupled to the interrupt-enabled input pin of the
processor, as described above. Furthermore, when transitioning from
the primary payment mode into the sleep mode, the payment card can
set an alternative (e.g., lower) input magnitude threshold for
detecting an input on the card in the sleep state or select an
alternative interrupt-enabled input pin of the processor to trigger
the processor to wake from the sleep state into the secondary
payment mode, as in Block S104 described below. Thus, in response
to expiration of the first timer before a card reader is detected
by the payment card, the payment card can execute Block S140 to
transition into the sleep in which the payment card operates at a
reduced power consumption setting with an increased sensitivity to
an input on its surface to wake from the sleep state into the
secondary payment mode.
[0041] The payment card can further maintain an authentication of
use of the payment card--confirmed in the primary payment mode in
Block S112--into the sleep mode and through subsequent transitions
between the sleep mode and the secondary payment mode until a card
reader is detected proximal the payment card and the selected
magnetic stripe card emulated by the magnetic stripe emulator in a
subsequent transaction, as in Block S190 described below. For
example, the payment card: can execute Block S112 once (i.e., one
time) in preparation for an upcoming transaction; can write
authorization of use of the payment card to local memory; can read
the authorization from the local memory in both the primary payment
mode and the secondary payment mode, as applicable, before
triggering the magnetic stripe emulator to emulate a selection
magnetic stripe card; and can clear the authorization of use of the
payment card once the magnetic stripe emulator completes an
emulation cycle to emulate the selected magnetic stripe card. In
this example, the payment card can also transition from the
secondary payment mode into the off state in response to completion
of the emulation cycle, repeat Block S110 to transition from the
off state into the primary payment mode in response to an input on
the surface of the payment card that exceeds the first input
magnitude threshold, and then repeat Block S112 to authenticate use
of the payment card in another transaction.
[0042] In the foregoing example, the payment card can also set a
third timer--such as for a duration of five seconds--in response to
completion of the emulation cycle, repeat the emulation cycle if a
magnetic read head is detected adjacent the payment card prior to
expiration of the third timer, and transition into the off state
and clear the authorization of use of the payment card in response
to expiration of the third timer; in particular, the payment card
can maintain authorization of the payment card for some time after
a first emulation cycle such that a second emulation cycle can be
performed by the magnetic stripe emulator within some time after
the first emulation cycle if the first emulation cycle was
unsuccessful in communicating magnetic stripe data into the card
reader without necessitating re-authorization of the payment card
for the transactions. Thus, in the example above in which the user
wakes the payment card from the off state into the primary payment
mode, the payment card automatically authorizes use of the payment
card by establishing a wireless connection with the user's
smartphone, the user hands the payment card to a barkeeper, and the
barkeeper places the payment card aside until the user decides to
close out his tab: the payment card can transition into the
secondary payment card when barkeeper later handles the payment
card; can emulate a payment method selected earlier by the user
when the barkeeper swipes the payment card through a card reader;
can initiate the third timer (e.g., for five seconds) during or
upon completion of the emulation cycle; and can again emulate the
payment method when the barkeeper again swipes the payment card
through the card reader--such as if the previous attempt to read
the card was unsuccessful--if the card reader is detected by the
payment card before the third timer expires.
[0043] As shown in FIG. 6, one variation of the method includes
Block S142, which recites activating a fourth timer of a fourth
duration in response to transitioning from the primary payment mode
into the secondary payment mode--the fourth duration greater than
the first duration--and transitioning from the sleep state into the
off state in response to expiration of the third time. Generally,
Block S142 functions to set a timer defining a total duration of
time in which the payment card is authenticated for use in a
subsequent transaction. In particular, the payment card can execute
Block S142 when the payment card transitions from the off state
into the primary payment mode, when the payment card is
authenticated for use in Block S112, when a payment method (or
other magnetic stripe card) is selected for emulation in Block S114
or S116, or when the payment card transitions from the primary
payment mode into the sleep state; and the payment card can clear
an authorization of use of the payment card in response to
expiration of the fourth timer regardless of whether or not a card
reader has been detected near the payment card.
[0044] For example, the processor: can execute Block S120 to
initiate the first timer for the first duration of approximately
ninety seconds in response to entry into the primary payment mode
or in response to authentication of the payment card in Block S112;
can execute Block S142 to initiate the fourth timer for the fourth
duration of approximately two hours in response to authentication
of the payment card in Block S112 or in response to entry into the
secondary payment mode; and can execute Block S160 to initiate the
first timer for the first duration of approximately twelve-hundred
milliseconds in response to entry into the secondary payment mode.
In this example, the payment card can thus shut down (e.g., enter
the off state) or otherwise de-authorize use of the payment card in
an upcoming transaction if the fourth timer expires before a card
reader is detected near the payment card. Thus, as in the example
above in which the user hands the payment card to a barkeeper, the
payment card can initiate the fourth timer for a duration of four
hours, and the payment card can shut down--and thus disable a
payment feature of the payment card--if the user forgets the
payment card at the bar and does not return for it until the next
day, thereby precluding use of the payment card in any further
transactions until the user retrieves the payment card and the
payment card can reauthorize use in Block S112, as described
above.
[0045] However, the payment card can implement Block S142 in any
other way to initiate a timer of any other length, such as a static
fourth duration stored in memory in the payment card or a fourth
duration selected by the user through the native payment card
application executing on the mobile computing device and received
from the mobile computing device by the payment card via the
wireless communication module.
[0046] Block S150 of the method recites, in response to detecting
an input on the surface of the payment card exceeding a second
input threshold magnitude less than the first input threshold
magnitude in the sleep state, transitioning from the sleep state
into a secondary payment mode. Generally, Block S150 implements
methods or techniques similar to those of Block S110 to detect an
input on the payment card and to trigger the payment card to
transition out of the sleep state and into the secondary payment
mode, wherein the processor polls the magnetic read head sensor(s)
to detect an adjacent card reader for a limited duration of time in
the secondary payment mode. In particular, the payment card can
operate at a heightened sensitivity in the sleep state such that
simply picking up the payment card, jostling the payment card, or
even placing the payment card in a read slot of card reader outputs
a digital high voltage signal from the piezoelectric transducer,
which in turn throws an interrupt at the second `wake`
interrupt-enabled input pin of the processor, thereby triggering
Block S150 to transition the payment card out of the sleep state
and into the secondary payment mode to poll the magnetic read head
sensor(s) for a nearby card reader for a limited period to
time.
[0047] In one example, the processor executes Block S150 by
transitioning from the sleep state into the secondary payment mode
in response to a magnitude value of a signal output from the
piezoelectric transducer exceeding the second input threshold
magnitude. In this example, the piezoelectric transducer outputs a
signal of magnitude value exceeding the second input threshold
magnitude in response to an input on the surface of the payment
card that bends the surface out of plane by a second degree
substantially less than the first degree of the primary payment
mode described above. In another example, the processor samples a
sensor (e.g., an accelerometer, a tilt sensor) within the payment
card (e.g., at a secondary sampling rate in the sleep state slower
than a primary sampling rate implemented by the processor in the
off state), compares a form of an output of the sensor to the
second input threshold magnitude, and transitions from the sleep
state into the secondary payment mode in response to the form of
the second output of the sensor exceeding the second input
threshold magnitude, such as described above in Block S110.
[0048] In Block S150, the payment card can further set a limit to
sequential inputs that trigger transition into the second payment
mode. In particular, for handling of the payment card that
repeatedly wakes the payment card from the sleep state into the
secondary payment mode, the payment card can track a number and/or
frequency of transitions from the sleep state into the secondary
payment mode within a period of time and disable the trigger to
transition from the sleep state into the secondary payment mode
once a threshold number or frequency of transitions have occurred
within the period of time. For example, if the payment card is set
in the sleep mode and then placed on bar in a club with loud,
bass-heavy music, placed on rattling dashboard, or left in a
washing machine, the payment card can disable the transition
trigger for entering into the secondary payment mode once ten
transitions have occurred sequentially, once seven transitions have
occurred within a thirty-second period of time, and/or if a rate of
more than one transition per two-second interval has occurred
within a period of ten seconds, etc. The payment card can thus
prolong the life of an internal or integrated battery by disabling
repeated transitions into a higher-power setting (e.g., the
secondary payment mode). In this implementation, once the
transition trigger is disabled, the payment card can set a fifth
timer--such as for thirty seconds or one minute--and maintain the
transition trigger in the disabled state until the fifth timer
expires; once the fifth timer expires, the payment card can again
enable the transition trigger and transition from the sleep state
into the secondary payment mode in response to an input of
sufficient magnitude onto the card. The payment card in the sleep
state can thus emulate the off state by ignoring inputs of
magnitude less than the first input threshold magnitude until the
fifth timer expires. Alternatively, the payment card can transition
from the sleep mode into the off state in response to an excess
number and/or frequency of transitions from the sleep state into
the secondary payment mode, such as within a threshold period.
However, the payment card can handle an excess number and/or
frequency of transitions from the sleep state into the secondary
payment mode in any other way in Block S150. The payment card
implement similar methods or techniques to handle excess
transitions from the off state into the primary payment mode in
Block S110.
[0049] Block S160 of the method recites, in response to entering
the secondary payment mode, activating a second timer of a second
duration less than the first duration. Block S160 can similarly
recite, in the secondary payment mode, activating a second timer of
a second duration less than the first duration. Generally, once
Block S150 detects an input on the payment card and transitions the
payment card from the sleep state into the secondary payment mode,
Block S160 functions to set a second timer specifying a limited
period of time during which the processor will poll the magnetic
read head sensor(s) for a nearby card reader in Block S110 before
Block S180 transitions the payment card back into the sleep
mode.
[0050] In one example, Block S160 initiates the second timer
specifying a duration of five-hundred milliseconds such that Block
S180 transitions the payment card out of the secondary payment mode
and back into the lower-power sleep state if the payment card is
not used in a transaction within five-hundred milliseconds of the
transition into the secondary payment mode in Block S150. Block
S160 can thus set and trigger the second timer on the payment card
to limit durations of time in which the processor polls the
magnetic read head sensor(s) to periods characterized by events
most likely to lead to use of the payment card at a card reader. In
particular, the processor can execute Block S160 to initiate the
second timer for a limited period of time in response to detected
handling of the payment card (e.g., as detected by subtle
deflection or other minimal input on the payment card), which may
occur just before the payment card is swept through a card reader
during a transaction. However, Block S160 can set the second timer
at any other suitable duration (e.g., between one-hundred
milliseconds and one second) locally on the payment card and can
initiate the second timer in response to any other suitable
transition event at the payment card.
[0051] Block S180 of the method recites, in response to expiration
of the second timer prior to detecting a magnetic read head
proximal the payment card, transitioning from the secondary payment
mode into the sleep state. Generally, Block S180 functions to
transition the payment card from the second payment mode back into
the sleep state if the magnetic read head sensor(s) fails to detect
a card reader (e.g., a magnetic read head) proximal the payment
card prior to expiration of the second timer. The payment card can
thus repeat Blocks S180, S150, and S160 to cycle the payment card
between the low-power, high-sensitivity sleep state and the
high(er)-power second payment mode in response to detected handling
of the payment card (e.g., as the payment card is picked up,
jostled, or otherwise manipulated) and in response to expiration of
the second timer until an adjacent card reader is detected in Block
S110 and an emulation cycle initiated at the magnetic stripe
emulator. Thus, as described above, the payment card can maintain
authentication of the payment card for use--as originally set in
Block S112--throughout cycles of Blocks S180, S150, and S160 until
a transaction with the payment card is initiated by proximity of
the payment card to a card reader.
[0052] Block S170 of the method recites, in response detecting a
magnetic read head proximal the payment card prior to expiration of
the second timer, transitioning from the secondary payment mode
into the off state. Block S110 can similarly recite, in response
completion of the emulation cycle, transitioning from the secondary
payment mode into the off state. Generally, Block S110 implements
methods or techniques similar to those of Block S130 to poll a
magnetic read head sensor, to detect a magnetic read head (or other
card reader) adjacent the payment card, to trigger Block S190 to
drive the magnetic stripe emulator according to a magnetic sequence
command corresponding to a magnetic stripe card selected in Block
S114 or S116, and to transition the payment card from the secondary
payment mode into the off state once payment method data is
communicated into the card reader in Block S190. The processor can
thus execute Block S110 to transition the payment card out of the
secondary payment mode and into the off state (i.e., a
low(er)-power, low(er)-input sensitivity state), and the processor
can further remove an authentication status of the payment card
once the payment card transitions back into the off state in Block
S110 such that use of the payment card must be authenticated once
again before the payment card can be used in a subsequent
transaction to emulate a payment method or other magnetic stripe
card.
[0053] In one example, the payment card implements Block S150 by
responding to deflection of the payment card as the payment card is
placed in a slot of a card reader and transitions the payment card
into the secondary payment mode accordingly; the payment card
further implements Block S160 by setting the second timer to a
default duration of five-hundred milliseconds. The processor then
interfaces with a magnetic read head sensor within the payment card
adjacent a leading edge of the magnetic stripe emulator in Block
S110 to detect a magnetic read head within the card reader prior to
expiration of the second timer (i.e., within five-hundred
milliseconds), and the processor triggers the magnetic stripe
emulator to output a magnetic sequence corresponding to the elected
payment method (i.e., according to the corresponding magnetic strip
sequence command) in Block S190 before transitioning the payment
card back into the off state in Block S180.
[0054] However, the payment card can implement Blocks S150, S160,
S170, and S180 in any other way to intermittently transition the
payment card between the sleep state in which functions of the
payment card are suppressed and the secondary payment mode in which
the payment card emulates a selected magnetic stripe card when an
adjacent card reader is detected.
9. Transaction
[0055] Block S190 of the method recites, in the primary payment
mode and in the secondary payment mode, in response to detecting a
magnetic read head proximal the payment card, driving a magnetic
stripe emulator within the payment card according to a magnetic
sequence command stored on the payment card and corresponding to a
magnetic stripe card. Block S190 can similarly recite, in the
secondary payment mode, in response to detecting a magnetic read
head proximal the payment card prior to expiration of the second
timer, driving a magnetic stripe emulator within the payment card
during an emulation cycle according to a magnetic sequence command
stored on the payment card and corresponding to a static magnetic
stripe card. Generally, the payment card executes Block S190 to
drive the magnetic stripe emulator according to a magnetic sequence
command corresponding to the payment method--or other magnetic
stripe card selected for the transaction in Block S114 or Block
S116--in response to detecting an adjacent card reader and/or in
response to detecting movement of the payment card through an
adjacent card reader (e.g., in Block S130 or in Block S170). For
example, the processor can execute Block S190 to prompt the
magnetic stripe emulator to mimic (e.g., emulate, replicate) an
output of the original magnetic stripe card (e.g., a credit card, a
debit card, a gift card) selected for the transaction, such as
described in U.S. patent application Ser. No. 13/904,939.
[0056] Furthermore, with the payment card in the primary payment
mode, once the magnetic stripe emulator completes transmission of a
magnetic sequence corresponding to the elected payment method
(i.e., an "emulation cycle"), the processor can transition the
payment card back into the off state, as in Block S130. Similarly,
with the payment card in the secondary payment mode, once the
magnetic stripe emulator has completed an emulation cycle according
to the magnetic sequence command corresponding to the elected
magnetic stripe card, the processor can transition the payment card
back into the off state, as in Block S170.
[0057] In one implementation, in the primary payment mode, the
magnetic stripe emulator emulates a static magnetic stripe of a
particular payment method--selected for the transaction in Block
S114--in response to detecting a magnetic read head proximal the
payment card in Block S190. In the primary payment mode, the
processor polls a magnetic read head sensor arranged within the
payment card (e.g., at a sampling rate of 20 Hz) while the first
timer is active, and the processor then triggers the controller to
drive the magnetic stripe emulator according to the magnetic
sequence command corresponding to the particular payment method in
response to an output of the magnetic read head sensor indicating
proximity of a magnetic read head adjacent the payment card
occurring before expiration of the first timer. Furthermore, in
this implementation, in the secondary payment mode, the processor
polls the magnetic read head sensor while the second timer is
active and then triggers the controller to drive the magnetic
stripe emulator according to the (same) magnetic sequence command
corresponding to the (same) selected payment method in response to
an output of the magnetic read head sensor corresponding to
proximity of a magnetic read head adjacent the payment card
occurring prior to expiration of the second timer.
[0058] Alternatively, as described above, in the primary payment
mode, the processor can trigger the controller to drive the
magnetic stripe emulator according to a first magnetic sequence
command corresponding to a primary payment method selected for the
transaction in response to an output of the magnetic read head
sensor corresponding to proximity of a magnetic read head adjacent
the payment card occurring prior to expiration of the first timer.
Furthermore, in the secondary payment mode, the processor can
trigger the controller to drive the magnetic stripe emulator
according to a second magnetic sequence command corresponding to a
secondary payment method selected for the transaction in response
to an output of the magnetic read head sensor corresponding to
proximity of a magnetic read head adjacent the payment card
occurring prior to expiration of the second timer, wherein the
secondary payment method (e.g., secondary magnetic stripe card) is
distinct from the primary payment method (or primary magnetic
stripe card).
[0059] However, the payment card can implement Block S190 in any
other way to emulate one or more elected magnetic stripe cards in
the primary payment mode and in the secondary payment mode.
10. Input Threshold Magnitudes
[0060] As shown in FIG. 5, one variation of the method includes
Block S102, which recites, at the payment card, in the off state,
applying a first input threshold magnitude for detecting an input
on a surface of the payment card. In this variation, the method can
further include Block S104, which recites, in the sleep state,
applying a second input threshold magnitude for detecting an input
on the surface of the payment card, the second input threshold
magnitude less than the first input threshold magnitude. Generally,
Block S102 functions to set, select, or apply a first sensitivity
of the payment card to an input to trigger transition from the off
state into the primary payment mode, and Block S104 functions to
set, select, or apply a first a second sensitivity of the payment
card to an input to trigger transition from the sleep state into
the secondary payment mode. In particular, in the off state, the
payment card exhibits a first sensitivity to an input mechanism for
triggering transition out of the off state (and into the primary
payment mode) such that the payment card executes Block S110 in
response to an input (e.g., impact) a first magnitude onto a
surface of the payment card; in the sleep state, the payment card
exhibits a second sensitivity--greater than the first
sensitivity--to the input mechanism to trigger transition out of
the sleep state (and into the secondary payment mode) such that the
payment card executes Block S150 in response to an input (e.g.,
impact) a second magnitude--(substantially) relatively less than
the first magnitude--onto the surface of the payment card.
[0061] In one implementation in which the payment card includes a
piezoelectric transducer, the piezoelectric transducer is
electrically coupled to a first `wake` interrupt-enabled input pin
of the processor via a first signal conditioning circuit within the
payment card and is electrically coupled to a second `wake`
interrupt-enabled input pin of the processor via a second signal
conditioning circuit within the payment card. In this
implementation, the first signal conditioning circuit defines a
first input voltage threshold to trigger a digital high voltage
signal to the first interrupt-enabled pin, and the second signal
conditioning circuit defines a second input voltage threshold--less
than the first input voltage threshold--to trigger a digital high
voltage signal to the second interrupt-enabled pin. For example,
the piezoelectric transducer can be electrically coupled to the
first interrupt-enabled input pin via a first Zener diode with a
first breakdown voltage of 3V, and the piezoelectric transducer can
be electrically coupled to the second interrupt-enabled input pin
via a second Zener diode with a second breakdown voltage of 1.8V.
In this implementation, the processor can execute Block S102 by
enabling the first interrupt-enabled input pin and disabling the
second interrupt-enabled pin when the payment card transitions into
the off state, and the processor can execute Block S104 by enabling
the second interrupt-enabled input pin and disabling the first
interrupt-enabled pin when the payment card transitions into the
sleep state.
[0062] In a similar implementation, the piezoelectric transducer
can be electrically coupled to a `wake` interrupt-enabled input pin
of the processor via a first signal conditioning circuit and a
second signal conditioning circuit in parallel with the first
signal conditioning circuit. As in the foregoing implementation,
the first signal conditioning circuit defines a first input voltage
threshold to trigger a digital high voltage signal to the first
interrupt-enabled pin, and the second signal conditioning circuit
defines a second input voltage threshold--less than the first input
voltage threshold--to trigger a digital high voltage signal to the
second interrupt-enabled pin. In this implementation, the first and
second signal conditioning circuits electrically coupled to and
selectively enabled and disabled by a latch (e.g., a bistable
multivibrator); the processor can thus execute Block S102 by
setting the latch to enable the first signal conditioning circuit
and to disable the second signal conditioning circuit when the
payment card transitions into the off state, and the processor can
execute Block S104 by setting the latch to enable the second signal
conditioning circuit and to disable the first signal conditioning
circuit when the payment card transitions into the sleep state.
[0063] In yet another implementation, the payment card includes a
first piezoelectric transducer coupled to a first `wake`
interrupt-enabled input pin of the processor and a second
piezoelectric transducer coupled to a second `wake`
interrupt-enabled input pin of the processor, wherein the second
piezoelectric transducer outputs a greater voltage and/or current
for an input of the same input magnitude than the first
piezoelectric transducer. For example, the first piezoelectric
transducer can be of a first size, and the second piezoelectric
transducer can be of a second size greater than the first size and
thus output a greater voltage that the first piezoelectric
transducer for an input of a particular magnitude (or rate), such
as shown in FIG. 5. Additionally or alternatively, the second
piezoelectric transducer can be arranged across the effective
center of the broad face of the payment card, and the first
piezoelectric transducer can be arranged near a corner of the broad
face of the payment card such that the second piezoelectric
transducer is more sensitive to an input on the payment card--that
deflects the broad face of the payment cad--than the first
piezoelectric transducer. In this implementation, the processor can
execute Block S102 by enabling the first interrupt-enabled input
pin and disabling the second interrupt-enabled pin when the payment
card transitions into the off state, and the processor can execute
Block S104 by enabling the second interrupt-enabled input pin and
disabling the first interrupt-enabled pin when the payment card
transitions into the sleep state.
[0064] Yet alternatively, the payment card can include
piezoelectric transducer coupled to an input pin of the processor,
and the processor can sample the input pin in both the off state
and the sleep state to trigger transition into the primary payment
mode and into the secondary payment mode, respectively. In this
implementation, the input pin of the processor can incorporate or
be electrically coupled to an analog-to-digital converter (e.g., an
8-bit A/D converter) within the processor; the processor can
implement Block S102 by setting a first digital threshold value
(e.g., "200") for triggering transition from the off state into the
primary payment mode when the payment card enters into the off
state, and the processor can implement Block S104 by setting a
second digital threshold value (e.g., "120") for triggering
transition from the sleep state into the secondary payment mode
when the payment card enters into the sleep state. The processor
can also adjust a sampling rate of the piezoelectric transducer
based on the state of the payment card, such as by setting a first
sampling rate of 2 Hz for the off state and setting a second
sampling rate of 10 Hz for the sleep state. The processor can
implement similar methods and techniques for detecting and handling
outputs of a motion sensor, mechanical sensor, or other sensor
within the payment card in response to an input on the surface of
the payment card.
[0065] However, the payment card can implement Block S102 and Block
S104 in any other way to set or adjust a sensitivity of the payment
card to an input thereonto based on a current (or upcoming) state
of the payment card.
[0066] The payment card can also respond to different input
mechanisms in Block S110 and in Block S150. For example, the
payment card can transition from the off state into the primary
payment mode in Block S110 in response to an input on the payment
card triggering an output of sufficient magnitude from a
piezoelectric transducer within the payment card and then
transition from the sleep state into the secondary payment mode in
Block S150 in response to an input on the payment card triggering
an output of sufficient magnitude from an accelerometer within the
payment card.
[0067] The systems and methods of the embodiments can be embodied
and/or implemented at least in part as a machine configured to
receive a computer-readable medium storing computer-readable
instructions. The instructions can be executed by
computer-executable components integrated with the application,
applet, host, server, network, website, communication service,
communication interface, hardware/firmware/software elements of a
user computer or mobile computing device, or any suitable
combination thereof. Other systems and methods of the embodiments
can be embodied and/or implemented at least in part as a machine
configured to receive a computer-readable medium storing
computer-readable instructions. The instructions can be executed by
computer-executable components integrated by computer-executable
components integrated with apparatuses and networks of the type
described above. The computer-readable medium can be stored on any
suitable computer readable media such as RAMs, ROMs, flash memory,
EEPROMs, optical devices (CD or DVD), hard drives, floppy drives,
or any suitable device. The computer-executable component can be a
processor, though any suitable dedicated hardware device can
(alternatively or additionally) execute the instructions.
[0068] As a person skilled in the art will recognize from the
previous detailed description and from the figures and claims,
modifications and changes can be made to the embodiments of the
invention without departing from the scope of this invention as
defined in the following claims.
* * * * *