Field-powered biometric device, and method of controlling a field-powered biometric device

Abstract

A method of controlling operation of a field-powered biometric device comprising biometric acquisition circuitry, processing circuitry controllable to transition between a first functional state having a first power consumption and a second functional state having a second power consumption lower than the first power consumption, and power management circuitry. The method comprises the steps of monitoring, by the power management circuitry, a property indicative of a supply voltage to the processing circuitry; controlling, when the monitored property indicates that the supply voltage has fallen to a first threshold voltage, the processing circuitry to transition from the first functional state to the second functional state; and controlling, when the monitored property indicates that the supply voltage has increased to a second threshold voltage higher than the first threshold voltage, the processing circuitry to transition from the second functional state to the first functional state.

Claims

1. A field-powered biometric device using electrical power harvested from a time-varying electrical field for acquiring and performing operations on a biometric representation of a user, said field-powered biometric device comprising: biometric acquisition circuitry for acquiring the biometric representation of the user; processing circuitry connected to said biometric acquisition circuitry for receiving the biometric representation from said biometric acquisition circuitry and performing said operations on the biometric representation, said processing circuitry being controllable to transition between a first functional state exhibiting a first power consumption and a second functional state exhibiting a second power consumption lower than said first power consumption; power management circuitry connected to said processing circuitry, said power management circuitry being configured to: monitor a property indicative of a supply voltage to said processing circuitry; control, when said monitored property indicates that said supply voltage has fallen to a first threshold voltage, said processing circuitry to transition from said first functional state to said second functional state; and control, when said monitored property indicates that said supply voltage has changed from said first threshold voltage to a second threshold voltage higher than said first threshold voltage, said processing circuitry to transition back from said second functional state to said first functional state, wherein: said processing circuitry is controllable to a third functional state in which said processing circuitry saves settings to prepare for shut-down to be able to resume operation when the supply voltage is later improved, and said processing circuitry erases cryptographic and/or biometric data stored by the field-powered biometric device in the third functional state; and said power management circuitry is further configured to: control, when said monitored property indicates that said supply voltage falls below a third threshold voltage lower than said first threshold voltage, said processing circuitry to transition from said second functional state to said third functional state.

2. The field-powered biometric device according to claim 1, wherein said processing circuitry is configured to: pause said operations on the biometric representation when being transitioned from said first functional state to said second functional state; and resume said operations on the biometric representation when being transitioned back from said second functional state to said first functional state.

3. The field-powered biometric device according to claim 1, further comprising an energy storage device arranged and configured to: receive current and store electrical energy when an available electrical power harvested from the electrical field is greater than a required electrical power needed for operation of said field-powered biometric device; and provide current to the processing circuitry when the available electrical power harvested from the electrical field is less than the required electrical power needed for operation of said field-powered biometric device.

4. The field-powered biometric device according to claim 3, wherein said energy storage device comprises a capacitor.

5. The field-powered biometric device according to claim 1, further comprising clock signal providing circuitry connected to said processing circuitry for providing a clock signal to said processing circuitry, said clock signal providing circuitry being configured to provide said clock signal with a constant clock frequency to said processing circuitry, regardless of whether the processing circuitry is in said first functional state or in said second functional state.

6. The field-powered biometric device according to claim 1, wherein said power management circuitry is further configured to: disconnect, when said monitored property indicates that said supply voltage has fallen to said first threshold voltage, said clock signal providing circuitry from said processing circuitry; and reconnect, when said monitored property indicates that said supply voltage has changed from said first threshold voltage to said second threshold voltage, said clock signal providing circuitry to said processing circuitry.

7. The field-powered biometric device according to claim 1, further comprising energy harvesting circuitry connected to said biometric acquisition circuitry, to said processing circuitry, and to said power management circuitry, for: interacting with said time-varying electrical field to transform wireless energy from the electrical field to AC-power in said field-powered biometric device; and converting said AC-power to DC-power.

8. The field-powered biometric device according to claim 7, wherein said energy harvesting circuitry comprises a coil for interacting with said time-varying electrical field, and a rectifier connected to the coil.

9. The field-powered biometric device according to claim 1, further comprising voltage limiting circuitry arranged and configured to limit said supply voltage to the processing circuitry to a maximum supply voltage higher than said second threshold voltage.

10. The field-powered biometric device according to claim 1, wherein: said processing circuitry comprises a cryptographic block; and said processing circuitry, in said third functional state, further erases any data in said cryptographic block.

11. The field-powered biometric device according to claim 1, wherein said biometric acquisition circuitry comprises a fingerprint sensing arrangement.

12. A method of controlling operation of a field-powered biometric device comprising biometric acquisition circuitry, processing circuitry controllable to transition between a first functional state having a first power consumption and a second functional state having a second power consumption lower than said first power consumption, and power management circuitry, said method comprising the steps of: monitoring, by said power management circuitry, a property indicative of a supply voltage to said processing circuitry; controlling, when said monitored property indicates that said supply voltage has fallen to a first threshold voltage, said processing circuitry to transition from said first functional state to said second functional state; and controlling, when said monitored property indicates that said supply voltage has increased to a second threshold voltage higher than said first threshold voltage, said processing circuitry to transition from said second functional state to said first functional state, wherein: said processing circuitry is controllable to a third functional state in which said processing circuitry saves settings to prepare for shut-down to be able to resume operation when the supply voltage is later improved, and said processing circuitry erases cryptographic and/or biometric data stored by the field-powered biometric device in the third functional state; and said method further comprises the step of: controlling, when said monitored property indicates that said supply voltage falls below a third threshold voltage lower than said first threshold voltage, said processing circuitry to transition from said second functional state to said third functional state.

13. The method according to claim 12, wherein: when said monitored property indicates that said supply voltage has fallen to the first threshold voltage, said processing circuitry is controlled to pause operations on a biometric representation of a user; and when said monitored property indicates that said supply voltage has changed from said first threshold voltage to the second threshold voltage, said processing circuitry is controlled to resume said operations on the biometric representation of the user.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) These and other aspects of the present invention will now be described in more detail, with reference to the appended drawings showing an example embodiment of the invention, wherein:

(2) FIG. 1a is an illustration of an exemplary field-powered biometric device according to an embodiment of the present invention, in the form of a so-called contactless smart card;

(3) FIG. 1b is a schematic view of the smart card in FIG. 1a, when delaminated to reveal the functional parts of the smart card;

(4) FIG. 2 is a schematic block diagram of a field-powered biometric device according to an embodiment of the present invention;

(5) FIG. 3 is a flow-chart illustrating a method according to an embodiment of the present invention; and

(6) FIG. 4 is a diagram schematically illustrating operation of the field-powered biometric device in FIG. 2 in accordance with the method according to the flow-chart in FIG. 3.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

(7) In the present detailed description, various embodiments of the field-powered biometric device according to the present invention are mainly described with reference to a field-powered biometric device including a fingerprint sensing arrangement for acquiring a biometric representation in the form of a fingerprint image. Furthermore, the field-powered biometric device is described as included in a contactless smart card (which is itself a field-powered biometric device). It should be noted that field-powered biometric devices including various other kinds of biometric acquisition circuitry fall within the scope defined by the claims. Moreover, the field-powered biometric device according to embodiments of the present invention is not limited to being included in (or being) a contactless smart card.

(8) FIG. 1a schematically illustrates a first example embodiment of a field-powered biometric device according to the present invention, in the form of a so-called contactless smart card 1 including a biometric module 3. It should be noted that the biometric module 3, is also a field-powered biometric device.

(9) As is schematically shown in FIG. 1b, the smart card 1 additionally comprises an antenna 5, and a secure element 7. The antenna 5 is used for harvesting electrical power from a time-varying electrical field, and for wirelessly communicating with a remote device, such as a card reader (not shown), typically through load modulation. The secure element 7 may, for example, contain information for authorizing a transaction, and is connected to the biometric module 3. When the user is authenticated by the biometric module 3 (or by the biometric module 3 in co-operation with the secure element 7), the information contained in the secure element 7 may be unlocked and allowed to be wirelessly communicated to the card reader via the antenna 5.

(10) FIG. 2 is a schematic block diagram of a field-powered biometric system 10 including a power harvesting circuit 12 and a biometric module 3.

(11) The power harvesting circuit 12 comprises a coil (antenna) 5, and a rectifier 14. The biometric module 3 comprises biometric acquisition circuitry, here in the form of a fingerprint sensor 16, processing circuitry, here in the form of a microprocessor 18, power management circuitry 20, clock signal providing circuitry, here in the form of an oscillator 22, voltage limiting circuitry, here in the form of a shunt 24, and an energy storage device in the form of a capacitor 26.

(12) As is schematically indicated in FIG. 2, the fingerprint sensor 16, the microprocessor 18, the power management circuitry 20, the oscillator 22, the shunt 24 and the energy storage capacitor 26 are all connected in parallel with the rectifier 14 of the power harvesting circuit 12 to receive a rectified supply voltage V.sub.supply from the rectifier 14. The microprocessor 18 is coupled to the fingerprint sensor 16 to control operation of the fingerprint sensor 16 and to receive a biometric representation (a fingerprint representation) from the fingerprint sensor 16. The oscillator 22 is coupled to the microprocessor 18 and to the fingerprint sensor 16 to provide a clock signal having a substantially constant clock frequency to the microprocessor 18 and to the fingerprint sensor 16. The power management circuitry 20 is coupled to the microprocessor 18, and to a controllable switch 28 arranged between the oscillator 22, and the microprocessor 18 and the fingerprint sensor 16. The microprocessor 18 is controllable between at least a first functional state exhibiting a first power consumption and a second functional state exhibiting a second power consumption, lower than the first power consumption. In the first functional state, the microprocessor 18 may be in full operation and capable of performing various operations on a biometric representation received from the fingerprint sensor 16, and in the second functional state, the microprocessor 18 may be in a low-power state in which any ongoing operations may be paused and put on hold.

(13) The power harvested from the electrical field by the power harvesting circuit 12 will depend on the electrical field strength. If the power harvested from the electrical field is greater than the power needed by the biometric module 3, the voltage output by the rectifier 14 will increase to a predefined maximum voltage V.sub.max limited by the shunt 24. As is well-known to one of ordinary skill in the art, a shunt allows current to flow through the shunt to thereby maintain the voltage at the voltage for which the shunt is designed.

(14) A method according to an embodiment of the present invention will now be described with reference to the flow-chart in FIG. 3, and with additional reference, where applicable, to FIG. 2 and FIG. 4.

(15) In a first step 100, the supply voltage V.sub.supply is monitored by the power management circuitry 20. To this end, the power management circuitry 20 may, for example, comprise at least one comparator. One input of such a comparator may be connected to the supply voltage V.sub.supply and the other input may be connected to circuitry controllable to provide one of at least two threshold voltages V.sub.TH1 and V.sub.TH2. Depending on the previous level of the supply voltage V.sub.supply, such a comparator may be configured to compare the supply voltage V.sub.supply with either the first threshold voltage V.sub.TH1 or the second threshold voltage V.sub.TH2 (and/or any other threshold voltage being related to further functional modes of the microprocessor 18).

(16) It is here assumed that the harvested power provided by the power harvesting circuit 12 is initially sufficient to power the biometric module 3 with the microprocessor 18 operating in its first functional state. This means that the microprocessor 18 is initially in its first functional state, that the supply voltage V.sub.supply is higher than the first threshold voltage V.sub.TH1, and that the current I.sub.proc to the microprocessor is relatively high. The optional clock gating switch 28 in FIG. 2 is controlled by the power management circuitry 20 to be closed, so that the clock signal, with a substantially constant clock frequency, is provided to the microprocessor 18 and the fingerprint sensor 16. This initial point in time is indicated by the reference numeral 30 in the diagram in FIG. 4. The diagram in FIG. 4 is a somewhat simplified illustration of the supply voltage V.sub.supply over time for a situation when the power harvested from the electrical field by the power harvesting circuit 12 is not sufficient to support continuous operation of the biometric module 3.

(17) It is determined, in step 102, if the supply voltage V.sub.supply has fallen to the first threshold voltage V.sub.TH1. As long as this is not the case, the microprocessor 18 is allowed to remain in its first functional state and the supply voltage V.sub.supply is continuously monitored. This is indicated in FIG. 3 by the loop-back to from step 102 to step 100, and in the diagram in FIG. 4 by the time interval 32. If it is instead determined in step 102 that the supply voltage V.sub.supply has fallen to the first threshold voltage V.sub.TH1, which is indicated to occur at the time indicated by reference numeral 34 in the diagram in FIG. 4, then the method proceeds to the subsequent step 104 and the power management circuitry 20 controls the microprocessor 18 to transition to the second functional state, for example the operations carried out by the microprocessor 18 may be paused. Optionally, as is schematically indicated in FIG. 2, the clock gating switch 28 may be opened to prevent clock signals from being provided to (parts of) the microprocessor 18 and/or the fingerprint sensor 16. As is schematically indicated in the diagram in FIG. 4, the transition from the first functional state to the second functional state is allowed to take a predefined (and/or configurable) number of clock cycles, as is indicated by the time period labeled 36 in the diagram in FIG. 4.

(18) In the second functional state, the power consumption of the microprocessor 18 is considerably reduced. In other words, the current to the microprocessor 18 is considerably reduced. Then, the energy storage capacitor 26 in FIG. 2 is charged, resulting in an increasing supply voltage V.sub.supply, as is indicated by the time period 38 in the diagram in FIG. 4. During this time period 38, the power management circuitry 22 monitors the increasing supply voltage V.sub.supply in step 106.

(19) It is determined, in step 108, if the supply voltage V.sub.supply has risen to the second threshold voltage V.sub.TH2. As long as this is not the case, the microprocessor 18 is allowed to remain in its second functional state and the supply voltage V.sub.supply is continuously monitored. This is indicated in FIG. 3 by the loop-back to from step 108 to step 106. If it is instead determined in step 108 that the supply voltage V.sub.supply has risen to the second threshold voltage V.sub.TH2, which is indicated to occur at the time 40 in the diagram in FIG. 4, then the method proceeds to the subsequent step 110 and the power management circuitry 20 controls the microprocessor 18 to transition back to the first functional state so that the operations can be resumed. At the same time, or somewhat earlier, the power management circuitry may control the clock gating switch 28 to closed again, if applicable. The method then returns to step 100 and alternates between active time periods 32 and inactive (wait) time periods 38 as is schematically indicated in the diagram in FIG. 4. Provided that the time period 36 is very small compared to the time periods 32 and 38, the proportion of time spent processing closely approximates I.sub.source/I.sub.proc, where I.sub.source is the current provided by the power harvesting circuit 12.

(20) In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measured cannot be used to advantage.