US2018358886A1PendingUtilityA1
Integrated solution for multi-voltage generation with thermal protection
Assignee: MACOM TECH SOLUTIONS HOLDINGS INCPriority: Jun 9, 2017Filed: Jun 9, 2017Published: Dec 13, 2018
Est. expiryJun 9, 2037(~10.9 yrs left)· nominal 20-yr term from priority
H02M 3/155H02M 3/1588H02M 2001/0045H02M 1/08H02M 1/32H02M 1/009H02M 1/0045H02M 1/327H02M 3/158Y02B70/10
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Claims
Abstract
A multi-voltage converter is described that includes integrated temperature-protection circuity. The converter may be used to bias radio-frequency components such as PIN diodes and gallium-nitride devices, and may include integrated bias-sequencing circuitry. Programmable output voltages as high as 30 volts and as low as −20 volts may be generated.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A voltage converter comprising:
a substrate on which the voltage converter is assembled; a supply voltage contact configured to receive electrical power from a power source having a positive voltage; a boost converter connected to the supply voltage contact and configured to convert a supply voltage received from the power source to a first voltage that is greater than the supply voltage and to a negative voltage; a low-dropout regulator configured to convert the first voltage to a second voltage that is less than the first voltage; a register configured to output a first control signal that sets at least the second voltage within a positive voltage range that is greater than zero volts; and a sequencing circuit assembled on the substrate and configured to apply the second voltage to a drain supply contact only when the negative voltage is provided to a gate contact.
2 . The voltage converter of claim 1 , wherein the supply voltage contact is the only contact for receiving power that powers the voltage converter.
3 . The voltage converter of claim 1 , wherein the supply voltage is between approximately 2.5 volts and approximately 7 volts.
4 . The voltage converter of claim 31 , wherein the temperature sensing circuitry comprises a temperature sensor located near switching transistors of the boost converter.
5 . The voltage converter of claim 31 , wherein the temperature control circuitry comprises a comparator and at least one logic gate and is configured to receive a signal from the temperature sensing circuitry and output a control signal that alters operation of the boost converter when an over-heat condition is sensed.
6 . The voltage converter of claim 5 , wherein the control signal causes termination of voltage conversion by the boost converter when an over-heat condition is sensed.
7 . The voltage converter of claim 5 , wherein the control signal causes a reduction of a value of a converted output voltage from the voltage converter when an over-heat condition is sensed.
8 - 9 . (canceled)
10 . The voltage converter of claim 1 , wherein the sequencing circuit comprises:
a first logic circuit that senses a voltage at the gate contact and controls application of the second voltage to the drain supply contact; and a second logic circuit that senses a voltage at the drain supply contact and controls application of the negative voltage to the gate contact.
11 . The voltage converter of claim 1 , wherein the boost converter is configured to output up to 80 mA for the second voltage and/or the negative voltage.
12 . The voltage converter of claim 1 , further comprising a bias driver configured to receive a bias voltage from the low-dropout regulator and switch an output bias voltage between two levels.
13 . The voltage converter of claim 1 arranged in a circuit to apply the second voltage and the negative voltage to a radio-frequency component.
14 . The voltage converter of claim 13 , wherein the radio-frequency component comprises a gallium-nitride transistor.
15 . The voltage converter of claim 1 , wherein the negative voltage has a value in a range from approximately −8 volts to approximately −20 volts.
16 . The voltage converter of claim 1 , wherein the first voltage has a value in a range from approximately 20 volts to approximately 35 volts.
17 . The voltage converter of claim 1 , wherein the boost converter comprises:
two transistors; two inductor contacts on the substrate that are connected to the two transistors; and switching circuitry configured to switch current through an inductor that attaches to the two inductor contacts.
18 - 30 . (canceled)
31 . The voltage converter of claim 1 , further comprising temperature sensing and control circuitry configured to sense an over-heat condition of the voltage converter.Cited by (0)
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