Abstract: A method (300) of identifying failing bits in a ferroelectric memory device including at least one ferroelectric capacitor includes (302) writing same state data to the first capacitor, and (304) baking the first capacitor for a first specified period of time at a first selected temperature. A same state read (306) is performed on the first capacitor after the baking. Based on the results from the same state read, it is determined whether an error occurred. The first specified period of time can be from 10 minutes to 2 hours and the first selected temperature can be in a range from 85° C. to 150° C. A repair can be performed (310) to corrected detected errors. A related method (500) can detect imprinted bits using a same state write (502), followed by a relatively high temperature bake (504), then a same state read (506). An opposite state date write (508) is performed followed by a relatively low temperature bake (510), and then an opposite state data read (512) to identify opposite state error or imprint.

Abstract: A method (300) of identifying failing bits in a ferroelectric memory device including at least one ferroelectric capacitor includes (302) writing same state data to the first capacitor, and (304) baking the first capacitor for a first specified period of time at a first selected temperature. A same state read (306) is performed on the first capacitor after the baking. Based on the results from the same state read, it is determined whether an error occurred. The first specified period of time can be from 10 minutes to 2 hours and the first selected temperature can be in a range from 85° C. to 150° C. A repair can be performed (310) to corrected detected errors. A related method (500) can detect imprinted bits using a same state write (502), followed by a relatively high temperature bake (504), then a same state read (506). An opposite state date write (508) is performed followed by a relatively low temperature bake (510), and then an opposite state data read (512) to identify opposite state error or imprint.

Abstract: The method includes storing a memory data state in the ferroelectric memory cell. An event will trigger the evaluation of signal margin on a memory cell. If the memory cell is identified to have a weak signal, the memory cell is exercised. Exercising includes either performing one or more data read/re-write events or performing one or more simulated data read and data write events of an alternating high data state and a low data state to the memory cell associated with the weak data bit. Both the lifetime retention testing and the memory data state exercising are performed in the background of normal memory operation.

Abstract: A method (300) of identifying failing bits in a ferroelectric memory device including at least one ferroelectric capacitor includes (302) writing same state data to the first capacitor, and (304) baking the first capacitor for a first specified period of time at a first selected temperature. A same state read (306) is performed on the first capacitor after the baking. Based on the results from the same state read, it is determined whether an error occurred. The first specified period of time can be from 10 minutes to 2 hours and the first selected temperature can be in a range from 85° C. to 150° C. A repair can be performed (310) to corrected detected errors. A related method (500) can detect imprinted bits using a same state write (502), followed by a relatively high temperature bake (504), then a same state read (506). An opposite state date write (508) is performed followed by a relatively low temperature bake (510), and then an opposite state data read (512) to identify opposite state error or imprint.

Abstract: One embodiment of the present invention relates to a method for reducing the imprint of a ferroelectric memory cell. The method comprises storing a memory data state in the ferroelectric memory cell. An event will trigger the evaluation of signal margin on a memory cell. If the memory cell is identified to have a weak signal, the memory cell is exercised. Exercising comprises either performing one or more data read/re-write events or performing one or more simulated data read and data write events of an alternating high data state and a low data state to the memory cell associated with the weak data bit. Both the lifetime retention testing and the memory data state exercising are performed in the background of normal memory operation. Other methods and circuits are also disclosed.

Abstract: Apparatus and methods are described for a multi-level FeRAM memory device. Using write and read circuits associated with the memory device, multiple data states may be written to and read from the ferroelectric memory device which are associated with a single polarization direction, thereby allowing for a single cell to contain more than one bit of data.

Abstract: Apparatus are provided for fatigue testing ferroelectric material in a wafer, including an on-chip oscillator to provide a bipolar waveform to a ferroelectric capacitor formed in the wafer, as well as a switching system to selectively provide external access to the ferroelectric capacitor. Test methods are also disclosed provided, including measuring a performance characteristic of a ferroelectric capacitor in the wafer, providing a bipolar waveform to the ferroelectric capacitor for a number of cycles using an on-chip oscillator, and again measuring the performance characteristic after an integer number of cycles of the bipolar waveform.

Abstract: The present invention facilitates evaluation of ferroelectric memory devices. A ferroelectric memory device is fabricated that comprises memory cells comprising ferroelectric capacitors (802). A short delay polarization value is obtained (804) by writing a data value, performing a short delay, and reading the data value. A long delay polarization value is obtained (806) by again writing the data value, performing a long delay, and again reading the data value. The short delay and long delay polarization values are compared (808) to obtain a data retention lifetime for the ferroelectric memory device. The obtained data retention lifetime is compared with acceptable values (810) and, if deemed unacceptable, avoids unnecessary performance of thermal bake data retention lifetime testing.

Abstract: Apparatus are provided for fatigue testing ferroelectric material in a wafer, including an on-chip oscillator to provide a bipolar waveform to a ferroelectric capacitor formed in the wafer, as well as a switching system to selectively provide external access to the ferroelectric capacitor. Test methods are also provided, including measuring a performance characteristic of a ferroelectric capacitor in the wafer, providing a bipolar waveform to the ferroelectric capacitor for a number of cycles using an on-chip oscillator, and again measuring the performance characteristic after an integer number of cycles of the bipolar waveform.

Abstract: Apparatus and methods are described for a multi-level FeRAM memory device. Using write and read circuits associated with the memory device, multiple data states may be written to and read from the ferroelectric memory device which are associated with a single polarization direction, thereby allowing for a single cell to contain more than one bit of data.

Abstract: The present invention can improve and/or modify data retention lifetimes for ferroelectric devices by baking them prior to or during packaging. A ferroelectric device is programmed to a particular state and then baked for a selected period of time at a selected temperature. This pre-baking or imprinting causes the device to be imprinted or have a preference for the particular state and reduces loss of signal margin over time, thereby at least partially preserving data retention capabilities.

Abstract: The present invention can improve and/or modify data retention lifetimes for ferroelectric devices by baking them prior to or during packaging. A ferroelectric device is programmed to a particular state and then baked for a selected period of time at a selected temperature. This pre-baking or imprinting causes the device to be imprinted or have a preference for the particular state and reduces loss of signal margin over time, thereby at least partially preserving data retention capabilities.

Abstract: Apparatus and methods are described for a multi-level FeRAM memory device. Using write and read circuits associated with the memory device, multiple data states may be written to and read from the ferroelectric memory device which are associated with a single polarization direction, thereby allowing for a single cell to contain more than one bit of data.

Abstract: Apparatus are disclosed for fatigue testing ferroelectric material in a wafer, comprising an on-chip oscillator to provide a bipolar waveform to a ferroelectric capacitor formed in the wafer, as well as a switching system to selectively provide external access to the ferroelectric capacitor. Test methods are also disclosed, comprising measuring a performance characteristic of a ferroelectric capacitor in the wafer, providing a bipolar waveform to the ferroelectric capacitor for a number of cycles using an on-chip oscillator, and again measuring the performance characteristic after an integer number of cycles of the bipolar waveform.

Abstract: Apparatus and methods are described for a multi-level FeRAM memory device. Using write and read circuits associated with the memory device, multiple data states may be written to and read from the ferroelectric memory device which are associated with a single polarization direction, thereby allowing for a single cell to contain more than one bit of data.