초록 ▼

Devices, such as mobile devices, may be exposed to short circuit and output overload events. To protect against such events, mobile devices typically include circuitry to limit currents so as not to exceed a pre-programmed current limit. Various embodiments of the present invention include devices a

Devices, such as mobile devices, may be exposed to short circuit and output overload events. To protect against such events, mobile devices typically include circuitry to limit currents so as not to exceed a pre-programmed current limit. Various embodiments of the present invention include devices and methods for detecting pre-programmed current limits and for limiting currents in response to such detection. In some embodiments, both the current limit detector and the current limit controller circuitry include scaled current switches. The scaling may be substantially similar between the programmed-current limit detector and the current limit controller circuitry.

대표청구항 ▼

What is claimed is: 1. A device for controlling current limits with a current limit detector, comprising: a current limit controller including a scaled transistor the scaled transistor adapted to drive a first current based on a control signal; a current limit detector adapted to detect a user-defi

What is claimed is: 1. A device for controlling current limits with a current limit detector, comprising: a current limit controller including a scaled transistor the scaled transistor adapted to drive a first current based on a control signal; a current limit detector adapted to detect a user-defined current limit and to activate the scaled transistor in response to the user-defined current limit; and a current limit portion including an amplifier adapted to generate the control signal, a large scale transistor of a predetermined large scale and a small scale transistor of a predetermined small scale, wherein a ratio between the predetermined large and small scales is preset to control a ratio between a small scale current and a large scale current flowing to the small and large scale transistors, respectively, the small and large scale currents switch being regulated by responsive to the control signal the amplifier generating the control signal by comparing the small scale current and the user-defined current limit, wherein the current limit controller includes a plurality of scaled transistors and wherein the output current includes a sum of currents flowing through the plurality of scaled transistors. 2. A device as in claim 1, wherein the output current is based on the user-defined current limit. 3. A device as in claim 1, wherein regulating the large and small scale currents includes, if the small scale current exceeds the user-defined current limit, reducing the large scale current. 4. A device as in claim 1, wherein regulating the large and small scale currents includes, if the small scale current is below the user-defined current limit, increasing the large scale current. 5. A device as in claim 1, wherein the amplifier is an operational amplifier that includes input terminals, and wherein for regulating the large and small scale currents the amplifier is further adapted to produce the control signal responsive to a differential input voltage applied at its input terminals, the differential input voltage being proportional to a difference between the small scale current and the user-defined current limit. 6. A device as in claim 5, further comprising a resistor coupled to and interposed between the input terminals of the amplifier and adapted to allow a differential current to flow through it, the differential current being based on the small scale current and the user-defined current limit, the differential current flowing through the resistor producing the differential input voltage. 7. A device as in claim 6, wherein the resistor includes a current sensing resistor. 8. A device as in claim 1, wherein the amplifier includes input terminals and wherein for regulating the large and small scale currents the amplifier is further adapted to produce the control signal responsive to a differential input voltage applied at its input terminals, the differential input voltage being proportional to a difference between the small scale current and the user-defined current limit. 9. A device as in claim 1, wherein regulating the large and small scale currents is carried out at a pace that depends on a gain of the amplifier. 10. A device as in claim 1, further comprising a current limit converter coupled to the output terminal of the small scale transistor. 11. A device as in claim 1 embodied in an integrated circuit (IC) or as a functional block in the IC. 12. A device as in claim 11, wherein the IC is adapted for use in a mobile device. 13. A device as in claim 1, wherein the scaled transistor has a scale different from the predetermined large scale. 14. A device as in claim 1, wherein the current limit detector includes one or more current switches, one of the current switches controlling activation of the scaled transistor. 15. A method for controlling current limits with a current limit detector, comprising: detecting a user-defined current limit by a current limit detector; generating a detector signal based on the user-defined current limit detected; receiving, at a current limit controller with a plurality of scaled transistors, the detector signal; activating one or more of the plurality of scaled transistors in response to the detector signal; transmitting a first current through each activated scaled transistor, to a load, the first current based on a control signal; transmitting a large scale current through a large scale transistor, the large scale transistor being of a predetermined large scale, the large scale current based on the control signal; transmitting a small scale current through a small scale transistor, the small scale transistor being of a predetermined small scale such that a ratio between the predetermined large and small scales is preset to control a ratio between the large and small scale currents; comparing the small scale current and the user-defined current limit to generate the control signal; and using the control signal to regulate the large and small scale currents and the first current to maintain the small scale current below or near the user-defined current limit. 16. A method as in claim 15, wherein the using the control signal to regulate the large and small scale currents and each first current includes, if the small large scale current exceeds the user-defined current limit, modifying the control signal to reduce the large scale current, the small scale current and each first current. 17. A method as in claim 15, wherein the using the control signal to regulate the large and small scale currents and each first current includes, if the small scale current is below the user-defined current limit, modifying the control signal to increase the large scale current, the small scale current and each first current. 18. A method as in claim 15, wherein the using the control signal to regulate the large and small scale currents and each first current is further responsive to a differential input voltage being applied at input terminals inputs of an amplifier, the differential input voltage being proportional to a difference between the small scale current and the user-defined current limit. 19. A method as in claim 15, wherein the comparing is performed by an amplifier, and wherein the using the control signal to regulate the large and small scale currents and each first current is carried out at a pace that depends on a gain of the amplifier. 20. A method as in claim 15, wherein at least one of the plurality of scaled transistors has a scale different from the predetermined large scale. 21. A method as in claim 15, wherein the current limit detector includes one or more sealed current switches, one of the current switches controlling activation of each of the plurality of scaled transistors. 22. A device for controlling current limits, comprising: a plurality of scaled transistors operative to generate a current based on a control signal, wherein the generated current is the sum of currents flowing through the plurality of scaled transistors; a small scale transistor of a predetermined small scale adapted to conduct a small scale current and operative to modify the amplitude of the small scale current based on the control signal; a large scale transistor of a predetermined large scale adapted to conduct a large scale current and operative to modify the amplitude of the large scale current based on the control signal wherein a ratio between the predetermined large and small scales is preset to control a ratio between the large and small scale currents; and an amplifier adapted to generate the control signal based on the difference between the small scale current and a user-defined current limit.