Patents by Inventor Sriram Kalpat
Sriram Kalpat has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 7898059Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form a top electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: GrantFiled: April 20, 2009Date of Patent: March 1, 2011Assignee: Freescale Semiconductor, Inc.Inventors: Thomas P. Remmel, Peter Zurcher, Sriram Kalpat, Melvy F. Miller
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Publication number: 20090224365Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form a top electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: ApplicationFiled: April 20, 2009Publication date: September 10, 2009Applicant: FREESCALE SEMICONDUCTOR, INC.Inventors: Thomas P. Remmel, Sriram Kalpat, Melvy F. Miller, Peter Zurcher
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Patent number: 7535079Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form a top electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: GrantFiled: September 4, 2007Date of Patent: May 19, 2009Assignee: Freescale Semiconductor, Inc.Inventors: Thomas P. Remmel, Sriram Kalpat, Melvy F. Miller, Peter Zurcher
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Publication number: 20090061608Abstract: A method of depositing a silicon dioxide layer for a semiconductor device. The method includes depositing the silicon dioxide layer to have a silicon concentration of greater than 30 atomic percent and a nitrogen concentration of less than 5 atomic percent. The depositing includes flowing nitric oxide gas with a silicon precursor over a substrate. In one example, the silicon precursor and nitric oxide are flowed over a substrate with the substrate being at a temperature in a range of approximately 600 to approximately 900 degrees Celsius. In one example, the silicon dioxide layer is formed on a layer including charge storage memory material.Type: ApplicationFiled: August 29, 2007Publication date: March 5, 2009Inventors: Tushar P. Merchant, Lakshmanna Vishnubhotla, Ramachandran Muralidhar, Rajesh A. Rao, Sriram Kalpat
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Publication number: 20080001256Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form a top electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: ApplicationFiled: September 4, 2007Publication date: January 3, 2008Applicant: Freescale Semiconductors, Inc.Inventors: Thomas Remmel, Sriram Kalpat, Melvy Miller, Peter Zurcher
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Patent number: 7306986Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form atop electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: GrantFiled: June 9, 2005Date of Patent: December 11, 2007Assignee: Freescale Semiconductor, Inc.Inventors: Thomas P. Remmel, Sriram Kalpat, Melvy F. Miller, Peter Zurcher
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Publication number: 20070223636Abstract: A device and method for phase detection are disclosed. The device includes a phase differential module that provides a phase difference signal based on the phase difference between a data signal and a reference signal. The phase difference signal is provided to a first gate of a multi-gate fin-type field effect transistor (multi-gate FinFET) of the device. A second gate of the multi-gate FinFET transistor receives a bias signal that provides a phase detection threshold. A phase adjustment signal is provided at one or both of the FinFET current electrodes based on the phase difference signal and the bias signal.Type: ApplicationFiled: March 23, 2006Publication date: September 27, 2007Applicant: Freescale Semiconductor, Inc.Inventors: Mohamed Moosa, Leo Mathew, Sriram Kalpat
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Publication number: 20070176669Abstract: A device and method for temperature compensation of an electronic device are disclosed. The device includes a temperature bias controller with a temperature sensor. A bias signal based upon a signal from the temperature sensor is provided to a first gate of a multiple fin gate field effect transistor (multigate FinFET) transistor of a functional block. A second gate of the multigate FinFET transistor receives a control signal to control its operation within the functional block. In this configuration the first gate of the multigate FinFET transistor can be used for temperature compensation while the second gate is used for functional operation of the transistor. Specific embodiments of the present disclosure will be better understood with respect to the figures.Type: ApplicationFiled: January 31, 2006Publication date: August 2, 2007Applicant: Freescale Semiconductor, Inc.Inventors: Mohamed Moosa, Sriram Kalpat, Leo Mathew
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Publication number: 20070085153Abstract: A voltage controlled oscillator (VCO) has a plurality of series-connected inverters. Within each inverter a first transistor has a first current electrode coupled to a first power supply voltage terminal, a second current electrode, a first control electrode coupled to an output terminal of another inverter of the plurality of series-connected inverters, and a second control electrode for receiving a first bias signal. A second transistor has a first current electrode coupled to the second current electrode of the first transistor, a second current electrode coupled to a second power supply voltage terminal, and a first control electrode coupled to the first control electrode of the first transistor. The second control electrode of the first transistor of each inverter receives a same or separate analog control signal to adjust the threshold voltage of the first transistors thereof to affect frequency and phase of the VCO's signal.Type: ApplicationFiled: October 14, 2005Publication date: April 19, 2007Inventors: Sriram Kalpat, Leo Mathew, Mohamed Moosa, Michael Sadd, Hector Sanchez
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Publication number: 20070085721Abstract: An analog to digital converter including a plurality of multiple independent gate field effect transistors (MIGFET) that provide a plurality of digital output signals, is provided. Each MIGFET of the plurality of MIGFETs may have first gate for receiving an analog signal, a second gate for being biased, and a current electrode for providing a digital output signal from among the plurality of the digital output signals. Each MIGFET of the plurality of MIGFETs may have a combination of body width, channel length that is unique among the plurality of MIGFETs to result in a threshold voltage that is unique among the plurality of MIGFETs. A digital to analog converter including a plurality of MIGFETs is also provided.Type: ApplicationFiled: October 14, 2005Publication date: April 19, 2007Inventors: Mohamed Moosa, Sriram Kalpat, Leo Mathew
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Publication number: 20060220157Abstract: A gate dielectric structure (201) fabrication process includes forming a transitional dielectric film (205) overlying a silicon oxide film (204). A high dielectric constant film (206) is then formed overlying an upper surface of the transitional dielectric film (205). The composition of the transitional dielectric film (205) at the silicon oxide film (204) interface primarily comprises silicon and oxygen. The high K dielectric (206) and the composition of the transitional dielectric film (205) near the upper surface primarily comprise a metal element and oxygen. Forming the transitional dielectric film (205) may include forming a plurality of transitional dielectric layers (207) where the composition of each successive transitional dielectric layer (207) has a higher concentration of the metal element and a lower concentration of silicon.Type: ApplicationFiled: March 31, 2005Publication date: October 5, 2006Inventors: Sriram Kalpat, Voon-Yew Thean, Hsing Tseng, Olubunmi Adetutu
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Publication number: 20050272216Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form atop electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: ApplicationFiled: June 9, 2005Publication date: December 8, 2005Applicant: Motorola, Inc.Inventors: Thomas Remmel, Sriram Kalpat, Melvy Miller, Peter Zurcher
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Patent number: 6919244Abstract: A method of making a semiconductor device includes the steps of: providing a semiconductor substrate (110, 510, 1010, 1610) having a patterned interconnect layer (120, 520, 1020, 1620) formed thereon; depositing a first dielectric material (130, 530, 1030, 1630) over the interconnect layer; depositing a first electrode material (140, 540, 1040, 1640) over the first dielectric material; depositing a second dielectric material (150, 550, 1050, 1650) over the first electrode material; depositing a second electrode material (160, 560, 1060, 1660) over the second dielectric material; patterning the second electrode material to form a top electrode (211, 611, 1111, 1611) of a first capacitor (210, 710, 1310, 1615); and patterning the first electrode material to form a top electrode (221, 721, 1221, 1621) of a second capacitor (220, 720, 1320, 1625), to form an electrode (212, 712, 1212, 1612) of the first capacitor, and to define a resistor (230, 730, 1330).Type: GrantFiled: March 10, 2004Date of Patent: July 19, 2005Assignee: Motorola, Inc.Inventors: Thomas P. Remmel, Sriram Kalpat, Melvy F. Miller, Peter Zurcher