WO2013016305A2

WO2013016305A2 - Component analysis systems and methods

Info

Publication number: WO2013016305A2
Application number: PCT/US2012/047897
Authority: WO
Inventors: Wojciech Jakub POPPE; Ilyas Elkin; Puneet Gupta
Original assignee: Nvidia Corporation
Priority date: 2011-07-22
Filing date: 2012-07-23
Publication date: 2013-01-31
Also published as: TWI592674B; US20130021107A1; TW201323896A; TW201323900A; US9496853B2; WO2013016305A3; CN103650345A; DE112012003071T5; TWI472781B

Abstract

Component characteristics analysis systems and methods are described. In one embodiment, a ring oscillator comprises: at least one inversion stage operable to cause a signal transition; a target component that has an increased comparative impact or influence on a signal transition propagation in the ring oscillator; and an output component for outputting an indication of the impact the target component has on the signal transition. The target component can include a plurality of vias from one metal layer to another metal layer. The plurality of vias from one metal layer to another metal layer can be configured in a cell. The vias can correspond to a via layer. In one exemplary implementation, the output is coupled to an analysis component. The analysis component can include correlation of the via resistance into a wafer variations and generate a wafer map. The analysis component can include correlation of the via resistance into a wafer.

Description

COMPONENT ANALYSIS SYSTEMS AND METHODS

RELATED APPLICATIONS

This application claims benefit of and priority to:

Application Number 61/511 ,021 entitled "Digital Extraction of Via Resistance and Failure Rate" (Attorney Docket Number NVID-P-SC-11-0129-USO) filed on July 22, 2011;

Application Number 61/512,362 entitled "Digital Extraction of Metal Resistance and Capacitance" (Attorney Docket Number NVID-P-SC-11-0128-USO) filed on July 27, 2011;

Application Number 61/513,508 entitled "Digital Extraction of Via Resistance and Failure Rate" (Attorney Docket Number NVID-P-SC-11-0129-US02) filed on July 29, 2011;

Application Number 13/528,725 entitled "Coupling Resistance and Capacitance Analysis Systems and Methods" (Attorney Docket Number NVID-P-SC-11-0128-USO) filed on June 20, 2012; which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to examining semi-conductor chip component operations. In particular, the present invention relates to systems and methods for examining impacts associated component characteristics and features.

BACKGROUND OF THE INVENTION

Electronic systems and circuits have made a significant contribution towards the advancement of modern society and are utilized in a number of applications to achieve advantageous results. Numerous electronic technologies such as digital computers, calculators, audio devices, video equipment, and telephone systems have facilitated increased productivity and reduced costs in analyzing and communicating data in most areas of business, science, education and entertainment. The manner in which the electronic devices perform operations can have a significant impact on the performance and end results. However, traditional attempts at accurately analyzing impacts associated with different aspects of how a device operates are often limited and can be very complex and complicated.

As process dimensions shrink (e.g., with advancing semiconductor process generation, etc.), it usually becomes more and more difficult to consistently reproduce the same exact pattern. Process variability can cause significant yield fallout leading to wasted silicon. Via and contact variations are a significant cause of yield loss as they are very challenging to print and typically require very fine alignment between metal and via/contact layers. Via resistance measurement structures have been designed and implemented, but past traditional approaches generally require an analog resistance measurement (e.g., directly by oscilloscope, through a four-point probe approach, other methods, Kelvin techniques, etc.) or are very limited digital attempts (e.g., zero or infinite resistance, only detect opens, etc.) and usually involve extremely large number of vias (e.g., million vias, etc.). Since each wafer can have hundreds of chips and multiple via layers (e.g., up to a dozen or more, etc.), traditional attempts at more detailed or exhaustive measurement is usually very difficult and can involve

signification costs.

SUMMARY

Component characteristics analysis systems and methods are described. In one embodiment, a ring oscillator comprises: at least one inversion stage operable to cause a signal transition; a target component that has an increased comparative impact or influence on a signal transition (e.g., change, propagation, etc.) in the ring oscillator; and an output component for outputting an indication of the impact the target component has on the signal transition. The target component can include a plurality of vias from one metal layer to another metal layer. The plurality of vias from one metal layer to another metal layer can be configured in a cell. The vias can correspond to a via layer. In one exemplary implementation, the output is coupled to an analysis component. The analysis component can include correlation of the via resistance into wafer variations and generate a wafer map. The analysis component can include correlation of the via resistance into a wafer.

In one embodiment a method comprises: performing a dominant characteristic ring oscillation process; and analyzing results of the dominant characteristic ring oscillation process. The analysis can include determining a delay associated with a via resistance characteristic of a dominant characteristic ring oscillation process. The analysis can include correlating a delay associated with at least one of the dominant via resistance characteristic oscillation rings to a process variation. The analysis can include deconvolving (e.g., transistor speed, metal resistance, etc.).

DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments of the invention by way of example and not by way of limitation. The drawings referred to in this specification should be understood as not being drawn to scale except if specifically noted.

Figure 1 is a block diagram of an exemplary characteristic dominated ring oscillator in accordance with one embodiment of the present invention.

Figure 2 is a block diagram of exemplary characteristic dominated ring oscillator in accordance with one embodiment of the present invention.

Figure 3 is a block diagram of a cell in accordance with one embodiment of the present invention.

Figure 4 is a block diagram of side view through a portion of an integrated circuit in accordance with one embodiment of the present invention.

Figure 5 is a block diagram of a wafer map in accordance with one embodiment of the present invention. Figure 6 is a block diagram of a different via layer comparison map in accordance with one embodiment of the present invention.

Figure 7A is a graphical indication a lack of correlation with transistor speed in accordance with one embodiment of the present invention.

Figure 7B is a block diagram of a graphical indication of a high correlation with measure resistance.

Figure 8 is a block diagram of via resistance RO with different sensitivities to process variations in accordance with one embodiment of the present invention

Figure 9 is a block diagram of exemplary analysis system in accordance with one embodiment of the present invention.

Figure 10 is a block diagram of exemplary analysis system in accordance with one embodiment of the present invention.

Figure 11 is a flow chart of exemplary analysis method in accordance with one embodiment of the present invention.

Figure 12 is a flow chart of an exemplary analysis process in accordance with one embodiment of the present invention.

Figure 13 is a block diagram of exemplary a characteristic dominated ring oscillator system in accordance with one embodiment of the present invention.

Figure 14 is a block diagram of exemplary a characteristic dominated ring oscillator system in accordance with one embodiment of the present invention. Figure 15 is a block diagram of an exemplary metal analysis system in accordance with one embodiment of the present invention.

Figure 16 is a block diagram of an exemplary dominate characteristic ring oscillator in accordance with one embodiment of the present invention.

Figure 17 is a block diagram of an exemplary dominate characteristic analysis system in accordance with one embodiment of the present invention.

Figure 18 is a flow chart of an exemplary metal analysis method in accordance with one embodiment of the present invention.

Figure 19 is a flow chart of an exemplary dominate characteristic ring oscillation process in accordance with one embodiment of the present invention.

Figure 20 is a flow chart of an exemplary analysis process in accordance with one embodiment of the present invention.

Figure 21 is a block diagram of an exemplary coupling component in accordance with one embodiment of the present invention.

Figure 22 is a block diagram of an exemplary coupling component in accordance with one embodiment of the present invention.

Figure 23 is a block diagram of an exemplary transistor in accordance with one embodiment of the present invention.

Figure 24 is a block diagram of an exemplary transistor in accordance with one embodiment of the present invention.

Figure 25 is a block diagram of an exemplary capacitance modification configuration in accordance with one embodiment of the present invention. DETAILED DESCRIPTION

Reference will now be made in detail to the preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. While the invention will be described in conjunction with the preferred embodiments, it will be understood that they are not intended to limit the invention to these embodiments. On the contrary, the invention is intended to cover alternatives, modifications and equivalents, which may be included within the spirit and scope of the invention as defined by the appended claims. Furthermore, in the following detailed description of the present invention, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be obvious to one of ordinary skill in the art that the present invention may be practiced without these specific details. In other instances, well known methods, procedures, components, and circuits have not been described in detail as not to unnecessarily obscure aspects of the present invention.

The present systems and methods facilitate analysis of characteristics of various components (e.g., via resistance, contact resistance, etc.) and the characteristics can be utilized in various other analysis (e.g., manufacturing analysis, process analysis, etc.). In one embodiment, a novel characteristic dominated ring oscillator system includes a component or type of component (e.g., via resistances, contact resistances, etc.)that has an increased comparative impact or influence on a signal propagation in the ring oscillator (e.g., timing, delay, etc.). The resulting frequency can be analyzed for indications of the dominant component characteristics or features which can be utilized to determine indications of fabrication and operation problems. It is appreciated that a dominant characteristic component can impact or influence a signal transition propagation in a variety of ways. A dominant characteristic can impact a propagation of a signal transition from one component to another component. In one embodiment, a dominant characteristic component (e.g., via resistances, contact resistances, etc.) is coupled to the path of a ring oscillator. A dominant characteristic can impact signal transition changes from one state to another state (e.g., logical 0, logical 1, low voltage, high voltage, etc.). In one embodiment, a dominant characteristic component (e.g., via resistances, contact resistances, etc.) is coupled to the power supply path to inversion components of a ring oscillator. Additional information regarding dominant characteristic ring oscillators and analysis of the delay indications is set forth in following sections of the detailed description.

Figure 1 is a block diagram of exemplary characteristic dominated ring oscillator 100 in accordance with one embodiment of the present invention. Characteristic dominated ring oscillator 100 includes inversion component 111, inversion component 112, inversion component 113, target component 121, target component 122, target component 123, control component 140 and output 175. The inversion components are operable to cause at least one respective inversion transition in a signal. The transition or propagation of the inversion in the signal to a subsequent inversion component is impacted (e.g., delayed, etc.) by the respective "dominant" characteristics of target components 121, 122 and 123. In one embodiment, the target components (e.g., vias, contacts, etc.) include an increased or dominant resistive characteristic (e.g., increased via resistance, increased contact resistance, etc.). Control component 140 is operable to control a state of the signal. Output 175 is operable to output a signal.

In one embodiment, the dominant characteristic of a target component (e.g., via resistance, contact resistance, etc.) has an increased or greater comparative impact or influence on a signal transition or propagation (e.g., timing, delay, etc.) than another component (e.g., inversion component, control component, etc.). In one exemplary implementation, the increased impact influences the resulting output frequency. In one exemplary implementation, the greater or higher the resistance of a target component as compared to the resistance of another component (e.g., inversion component, control component, etc.) the greater or more proportionally significant the impact of the target component on the delay of a signal transition as compared to the other component resistance (e.g., inversion component resistance, control component resistance, etc.). In one embodiment, dominant target components in a particular oscillating ring are a homogenous type (e.g., via layer 2, via layer 3, metal layer 2, etc,).

In one embodiment, one innovative aspect includes adding a resistance load (e.g., via resistance, contact resistance, etc.) to target components or coupling components between other components (e.g., inverting stages, control components, etc.) of a ring oscillator. In one exemplary implementation, a coupling resistance load between the components or stages of the ring oscillator includes increasing the number of vias included in a coupling path of the dominant characteristic ring oscillator (e.g., more vias in a coupling path between two inverting stages, etc.). The vias can be added until the resistance associated with the vias has a dominant or increased impact on frequency changes associated with the ring oscillator path.

Figure 2 is a block diagram of exemplary via resistance dominated ring oscillator 200 in accordance with one embodiment of the present invention. Via resistance dominant ring oscillator 200 includes inversion component 211, inversion component 212, inversion component 213, via resistance dominant component 221, via resistance dominant component 222, via resistance dominant component 223, control component 230 and output 275. The inversion components are operable to cause at least one respective inversion transition in a signal. The via resistance dominant components couple the respective inversion components and propagate a signal between the respective inversion components. The transition or propagation (e.g., timing, delay, etc.) of the inversion in the signal to a subsequent inversion component is impacted by the respective dominant characteristic of the via resistance dominant coupling components (e.g., 221, 222, 223, etc.). Control component 230 is operable to control a state of the signal. In one embodiment, control component includes an AND gate 231 that is coupled to enable signal 232. Output 275 is operable to output a signal.

In one embodiment, the "additional" vias (e.g., 271, 272, 273, 274, 297, 298, 299, etc.) from one metal layer component (e.g., 241, 242, 248, 249, etc.) to another metal layer component (e.g., 251, 252, 258, 259, etc.) are included between two sequential inversion components (e.g., 212, 223, etc.). While "additional" vias are included between inversion components 212 and 223, it is appreciated that "additional" vias can be included between other components also (e.g., 211 and 212, 213 and 230, etc.). In one embodiment, the dominant via connections are between metal layers M2 and M3. In one exemplary implementation, the ring oscillator (RO) inverter stage connections traverse through a single type of via (e.g., a single via layer, via2 layer, etc.). The RO inverter stage connections can also traverse through a variety of via types (e.g., multiple via layers, etc.). In one embodiment, vias included in one metal later form the dominant via resistance and vias in other metal layers have a negligible impact on the via resistance to a signal transition propagation.

In one embodiment, the target components (e.g., connections, vias, contacts, etc.) between the RO inverter stages are significantly more resistant (e.g., 100 times, 500 times, 1000 times, etc.) than the resistance of other aspects of the RO inverter stages (e.g., transistors, etc.). In one embodiment, when the via or contact resistive load is significantly higher than the resistance of channel resistance of a driving transistor, the ring oscillator frequency can be more a function of via/contact chain resistance and not transistor speed. It is possible that transistor speed variation will not even need to be factored out. In one embodiment, a inversion component includes a low channel resistance driver. As the transistor speed becomes insignificant, the frequency can be more directly and consistently translated into via or contact resistance. In one embodiment in which one type of via or contact constitutes the dominant portion of the total resistance of an RO, the via or contact dominant RO can be used to digitally measure via or contact resistance on every chip.

In one embodiment, the via connections are organized in cells with a plurality of vias (e.g., 100, 250, etc.) included in a cell. Figure 3 is a top view block diagram of an exemplary cell in accordance with one embodiment of the present invention. The cell includes metal components shown typically as 320 in one metal layer and metal components shown typically as 310 in another metal layer that are selectively coupled by vias shown typically as 330. In one exemplary implementation, the metal components 320 in one metal layer are oriented in a first direction (e.g., parallel to a first side of a die, diagonal from the first side of a die, etc.) and the metal components 330 are oriented in an orthogonal direction from the first direction. A plurality (e.g., 2, 3, 4, etc.) of these cells can be strung between each stage, so each inverter drives through a via layer (e.g., via 2, via 3, etc.) multiple times (e.g., 200, 250, 300, etc.) in series. Figure 4 is a block diagram of side view through a portion of an integrated circuit in accordance with one embodiment of the present invention. The circuit includes a metal layer 410, a via layer 420, a metal layer 430, a via layer 440, a metal layer 450, a device layer 460, and a substrate layer 470.

The "additional" resistance between RO inverter stages (e.g., via2 level resistance, etc.) can increase the stage delay (e.g., 10 times, 20 times, etc.). In one embodiment, approximately 90% of the delay can come from or be attributed to the via2 resistance between RO inverter stages. In one exemplary implementation, a 10% change in transistor (TX) speed changes the frequency by 1% and a 10%> change in via resistance changes the frequency by 9%.

In one exemplary implementation, a RO is designed to oscillate at frequency limited by Via 2 resistance in which the inverter channel resistance is approximately 200 ohms (NOTE: not counting contact/metal resistance) and the inverter stage delay is approximately lOps ( the 3X Via chain cell resistance (e.g., 300 Via2s) is approximately 25,000 ohms) and the Via2 RO stage delay is approximately lOOps. In one exemplary implementation, via resistance is dominant and the RO frequency correlates with Via 2 resistance.

In one embodiment, dominant characteristic impacts a power supplied to a component of a ring oscillator which in turn impacts a signal transition in the ring oscillator. In one exemplary implementation, a dominant characteristic component (e.g., via resistances, contact resistances, etc.) is coupled in the path of the power supply path to inversion components of a ring oscillator. Figure 13 is a block diagram of exemplary

characteristic dominated ring oscillator system 1300 in accordance with one

embodiment of the present invention. Characteristic dominated ring oscillator system 1300 includes power supply system 1301 and oscillating ring 1302. Power supply system 1301 includes rail 1351, target component 1321 , target component 1322, target component 1323, target component 1329, programmable controller 1330 and rail 1352. Ring oscillator 1301 includes inversion components 1311, 1312, 1313 and 1314. In one embodiment, ring oscillator 1302 can include a control component (not shown) is operable to control a state of the signal (e.g., similar to control component 140, etc.) and an output operable to output a signal (e.g., similar to output 175, etc.).

The components of characteristic dominated ring oscillator system 1300 cooperatively operate to transition a signal (e.g., transition a signal logic state, transition a signal voltage level, etc.). The ring oscillator 1302 is operable to cause at least one respective inversion transition in a signal. The signal transition is impacted by the respective target components selected by the programmable controller 1330. In one embodiment, the transition or propagation of the inversion in the signal through the ring oscillator is impacted (e.g., delayed, etc.) by the power voltage level supplied to the inversion components of the ring oscillator. In one exemplary implementation, the power voltage level supplied to the inversion components 1311, 1312, 1313, 1314 and 1315 is determined in part by the respective selection or activation of target components (e.g., 1321, 1322, 1323 and 1329, etc.). It is appreciated that a ring oscillator can have various odd numbers (e.g., 3, 5, 7, etc.) of inversion components. In one exemplary implementation, the programmable controller includes sleep transistors (e.g., 1331, 1332, 1333, and 1339, etc.) which are selectively enabled (e.g., by EN1, EN2, EN3, ENn, etc.). The voltage supplied to rail 1302 is determined by the voltage drop from rail 1301 caused by a selected target component. The voltage drop can be from VDD. In one embodiment, in a control mode (e.g., EN0 active, etc.) VDD is shorted to the inversion component.

In one embodiment, the target components (e.g., vias, contacts, etc.) include an increased or dominant resistive characteristic (e.g., increased via resistance, increased contact resistance, etc.). In one embodiment, the dominant characteristic of a target component (e.g., via resistance, contact resistance, etc.) has an increased or greater comparative impact or influence on a signal transition or propagation (e.g., timing, delay, etc.) through the ring oscillator. In one exemplary implementation, the increased impact influences the resulting output frequency. In one exemplary implementation, the greater or higher the resistance of a selected target component the lower the voltage supplied to the inverters and the slower the transition in the signal. In one embodiment, the current supplied is DC and there is no or minimal AC which eliminates or greatly reduces impacts associated with capacitance. In one exemplary implementation, including the target component impact in the power supply feed eliminates or greatly reduces impacts associated with other components ring oscillator component processes (e.g., ring oscillator inverter fabrication process impacts can be factored out, etc.).

Figure 14 is a block diagram of exemplary characteristic dominated ring oscillator system 1400 in accordance with one embodiment of the present invention.

Characteristic dominated ring oscillator system 1400 is similar to characteristic dominated ring oscillator system 1300 except target component 1423 is a directed to a dominant characteristic of metal layer 2 instead of via layer 3. Characteristic dominated ring oscillator system 1400 includes power supply system 1401 and oscillating ring 1402. Power supply system 1401 includes rail 1451, target component 1421, target component 1422, target component 1423, target component 1429, programmable controller 1430 and rail 1452. Ring oscillator 1401 includes inversion components 1411, 1412, 1413, 1414 and 1415. In one exemplary implementation, the

programmable controller includes sleep transistors (e.g., 1431, 1432, 1433, 1439, etc.) which are selectively enabled (e.g., by ENl, EN2, EN3, ENn, etc.). In one embodiment, ring oscillator 1402 can include a control component (not shown) is operable to control a state of the signal (e.g., similar to control component 140, etc.) and an output operable to output a signal (e.g., similar to output 175).

The impact of the target components on a signal transition (e.g., state change, propagation, etc.) can be a function of various characteristics or features of the target components. The target components can include various properties (e.g., resistance, capacitance, etc.) that are a function of characteristics or processes associated with the target component (e.g., can be a function of M2/Via2/M3 misalignment, of size, of spacing, of etching, of metal filling, of CMP, etc.).

In one embodiment, RO frequency correlates with Via/contact resistance. The RO frequency and via contact resistance can be a function of various things lithography overlay misalignment, etching , CMP, etc.). In one embodiment, lithography has a very characteristic signature. In one exemplary implementation, lithography is very layout dependent. A small shift in one layout can indicate very significant shift in another layout.

In one embodiment, target components can be configured to correspond to or be indicative of various characteristics or features (e.g., misalignment, flaws, errors, other effects, etc.). In one embodiment, a layout or configuration of the components (e.g., via components, metal layer component etc.) in a via dominant resistive load is modified (e.g., change configuration, change width, change length, more lithographically sensitive, etc.) to make it more sensitive to various characteristics or features (e.g., misalignment, flaws, errors, other effects, etc.).

It is appreciated that a via type target component can include a variety of via resistance dominant characteristics (e.g., wide via, narrow via, numerous vias, etc.). In one exemplary implementation, if one type of RO with a particular sensitivity (e.g., narrow via enclosure, etc.) starts to deviate more strongly a determination can be made to attribute the deviation to a characteristic or feature (e.g., misalignment, flaws, errors, other effects, etc.) or whatever sensitivity the particular layout type has.

Figure 8 is a block diagram of via resistance RO with different sensitivities to process variations in accordance with one embodiment of the present invention. Configuration 810 indicates the first horizontal metal layer component 811, the second horizontal metal layer component 812 and the vertical via component 813 are configured to form a reduced coupling enclosure area. The reduced coupling enclosure area can be implemented for increased sensitivity to misalignment. Configuration 820 indicates that a shift in the vertical via component 823 moves the via outside or straddling the enclosure area and is not a good coupling of the first horizontal metal layer component 821 and the second horizontal metal layer component 822. Configuration 830 indicates the first horizontal metal layer component 831, the second horizontal metal layer component 832 and the vertical via component 833 are configured to form an enlarged coupling enclosure area. The enlarged coupling enclosure area can be implemented for reduced sensitivity to misalignment. Configuration 840 indicates that a shift in the vertical via component 843 does not move the via outside nor straddle the enclosure area and is still a reasonably good coupling of the first horizontal metal layer component 841, the second horizontal metal layer component 842. In one embodiment, the width of a via can be 50 nanometers and width of the metal component is 100 nanometers. In one exemplary implementation, the overhang of distance from the edge of a centrally located via to the edge or a metal layer is 50 nanometers.

In one embodiment, there are multiple via sensitive ROs with different sensitivities to process. In one exemplary implementation, a combination of ROs are examined for one via layer and the ROs help identify a root cause of problem. Programmable

misalignment can be used to quantify the amount of misalignment.

In one embodiment, the target component is sensitive to critical dimension or size. In one exemplary implementation, there is a relatively smaller critical dimension on the bottom of a via and there is a relatively bigger critical dimension on the top of a via.

The results of the RO output can be utilized as a fabrication process monitor. In one embodiment, the results are in a convenient digital form. The process monitoring can also be conveniently performed on various levels of granularity (e.g., per component, per chip, per wafer, etc.) and various types of failures (e.g., CP, FT, etc.). There can also be multiple test points or regions within a mask. The via and contact resistance changes can be used to estimate via and contact failure rates. In one embodiment, this can be done by having a minimum of one instance per chip and optimally more. In one exemplary implementation, some wafer level variation can be expected due to sheet resistance changes as well as etcher variation, but with a higher density of points, reticle or mask (lithography) level systematic can be identified.

With these results a wafer map can be used to detect resistance discontinuities at the wafer level. Figure 5 is a block diagram of a wafer map in accordance with one embodiment of the present invention. In graph 510 a strong striped pattern is shown. The table 51 1 indicates the top two chips have a 30% lower yield. In graph 510 a no or weak striped pattern is shown. Table 521 indicates 8 chips per reticle. In one embodiment, no other Via 2 test structure exists in every chip in the wafer. In one embodiment, even small changes in via resistance can form very noticeable patterns that can then be correlated to low yielding chips. Significant yield differences can then be used to extrapolate increased via failure rates. Hence correlating chip failure to discontinuities in via resistance across the wafer can be another tool for identifying yield detractors. In one embodiment, having at least one separate RO with a high via/contact resistance to inverter stage transistor resistance for a via and contact layer enables insight into via and contact layers that have a RO. Averaging multiple via/contact types or levels can also be used to subtract out wafer level signatures that reduce the existence of lithography driven defects. Finally bringup teams can also be focused on new issues as chips with higher via failure rates can be ignored. Process improvements can also be tracked and quantified in more metrics or greater granularity than just yield (e.g., via 2 resistance, indication of cause of yield problem, etc.). Figure 6 is a block diagram of a different via layer comparison map in accordance with one embodiment of the present invention. Graph 610 is for a Via 3 target component dominate ring oscillator. Graph 620 is for a Via 2 target component dominate ring oscillator. In one embodiment the same RO in same locations except with Via 3 dominated resistive load.

Figure 7A is a graphical indication a lack of correlation with transistor speed in accordance with one embodiment of the present invention. In one embodiment, the goal is to measure contact resistance and not transistor speed. Figure 7B is a block diagram of a graphical indication of a high correlation with measure resistance. In one embodiment, there is a strong correlation with contact resistance measured with a four point probe.

It is appreciated while the present description is often described in terms of via resistances a variety of resistances can also be analyzed (e.g., via resistance, contact resistance, etc.) to facilitate process monitoring. In one exemplary implementation, delay or transistor speed is translated into a digital value by a ring oscillator to increment a counter for a fixed period of time. The digital counter results can be read out by a variety of mechanisms (e.g., a scan chain, JTAG chain, etc.). Hence, ring oscillator (RO) frequencies can be very inexpensively measured on a high volume ATE tester as compared to traditional mechanism attempts.

Figure 9 is a block diagram of exemplary analysis system 900 in accordance with one embodiment of the present invention. Analysis system 900 includes characteristic dominant ring oscillator system 910 and analysis component 920. It is appreciated that the characteristic dominant ring oscillator system 910 can include a variety of implementations 100, 200, 1300, 1400, etc.). Characteristic dominant ring oscillator 910 can include at least one target component (e.g., 121, 221, 1321, 1421, etc.).

Characteristic dominant ring oscillator 910 can include at least one control component (e.g., 140, 230, etc.). It is also appreciated that analysis component 920 can include a variety of implementations. In one embodiment, an output of characteristic dominant ring oscillator 910 is fed into analysis component 920. The analysis component 920 can include components on chip with the characteristic dominant ring oscillator 910, components off chip from the characteristic dominant ring oscillator 910, combination of components on and off chip. It is also appreciated that the analysis component 920 can perform a variety of different analysis. In one exemplary implementation, the analysis can include transition delays, determination of resistance power consumption, manufacturing process compliance and defects, etc.

Figure 10 is a block diagram of exemplary analysis system 1000 in accordance with one embodiment of the present invention. Analysis system 1000 includes dominant characteristic ring oscillator 1010 and analysis component 1020. Dominant

characteristic ring oscillator 1010 includes an oscillating ring comprising inversion components 1011, 1012, 1013, target components 1021, 1022, 1023, and controller 1031 coupled in a ring path. Output 1004 is forwarded from dominant characteristic ring oscillator 1010 to analysis component 1020. Analysis component 1020 includes counter 1021 and processing component 1022. It is also appreciated that the analysis component 1020 can perform a variety of different analysis. In one exemplary implementation, the analysis can include transition delays, determination of resistance power consumption, manufacturing process compliance and defects, etc. Figure 11 is a flow chart of exemplary analysis method 1100 in accordance with one embodiment of the present invention. In one embodiment, analysis method 1100 is performed by an analysis component (e.g., 920, 1020, etc.).

In block 1110, a dominate characteristic ring oscillation process is performed. In one embodiment, the dominant characteristic ring oscillation process includes pull ups and pull downs of a signal wherein at least one transition of a signal inversion to a subsequent component is impacted by a dominate characteristic. The dominant characteristic can be associated with a target component characteristic. In one exemplary implementation, oscillation includes transitions between a logical 1 state to a logical 0 state. In one embodiment, the second logic state is the opposite or inverse of the first logic state. In one embodiment, a dominant characteristic impact (e.g., via resistance, contact resistance, etc.) increases or makes the transition propagation delay longer or greater than would otherwise take if the dominant characteristic was not impacting the transition. In one embodiment, the resulting delay is so large it dominates the ring oscillator frequency. In one exemplary implementation, the delay can be digitally measured.

In block 1120, an analysis process is performed. In one embodiment, results of the dominate characteristic via ring oscillation process (e.g., similar to block 1110, etc.) are analyzed. It is appreciated that a variety of different analysis can be performed. The analysis can give insight into various characteristics and features (e.g., metal via resistance and configuration, contact resistance and configuration, etc.) that can be used to improve process as well as improve process modeling. Significant deviation in any component (e.g., via layer, contact layer, metal layer, etc,) can be fed back to the process team. Getting this information from ring oscillators enables high volume data collection across many production lots, which facilitates more accurate statistical analysis of various issues (e.g., process drift, malfunctions, operation difficulties, etc.).

Figure 12 is a flow chart of exemplary analysis process 1200 in accordance with one embodiment of the present invention. In one exemplary implementation, analysis process 1200 is similar to the analysis process of block 1120. In one exemplary implementation, analysis process 1200 is similar to the analysis performed by an analysis component (e.g., 920, 1020, etc.).

In block 1210, an indication associated with a dominant characteristic is received. In one embodiment, the indication includes transitions in a signal in which at least one transition delay is impacted by a dominant characteristic.

In block 1220, a timing characteristic associated with a signal transition time (e.g., delay, etc.) is determined, wherein the transition timing is impacted by a dominant characteristic. In one embodiment, the timing characteristic is a delay in a signal transition from one component to another component. It is appreciated that a timing characteristic (e.g., transition delay, etc.) can be impacted by a variety of dominant characteristics (e.g., via resistance, contact resistance, high channel resistance, low channel resistance, high coupling capacitance, low coupling capacitance, etc.).

In block 1230, characteristics of a device are analyzed based upon the signal transition timing. In one embodiment the transition timing analysis includes analysis of a delay in a signal transition from one component to another component. It is appreciated that a variety of characteristics can be analyzed. In one embodiment, analysis of various component characteristics (e.g., metal layer characteristics, via layer characteristics, contact characteristics, etc.) is performed. The target components can include various properties (e.g., resistance, capacitance, etc.) and characteristics or processes associated with the target component properties or sensitivities (e.g., can be a function of

M2/Via2/M3 misalignment, of size, of spacing, of etching, of CMP, etc.) can be analyzed. Various items can be analyzed at a various levels (e.g., chip level , wafer level, systematic level, etc.). Various statistical analysis (e.g., averaging, etc.) can be performed to factor out anomalies (e.g., wafer level signatures, etc.). In one

embodiment, if dominate characteristic ring oscillator system has a particular characteristic (e.g., 100,000 vias in a target component and a 10% increase in resistance, etc.) then various extrapolation can be made (e.g. there will be a via failure in 1,000,000 vias, etc.). In one exemplary implementation, the signal transition timing (e.g., delay times, etc.) can be utilized to examine fabrication processes and device operations. The transition delays can be utilized to extrapolate resistance measurements and coupling capacitance measurements for components included in an oscillating ring and other components of a semiconductor chip. The other components can include components in an area of a semiconductor chip close to components or with similar characteristics of components of a dominant character ring oscillator (e.g., 100, 200, etc.). In one exemplary implementation, measurements associated with a dominant characteristic (e.g., via resistance, contact resistance, line metal resistance, etc.) of ring oscillators is extrapolated based upon transition delays in the ring oscillators. The measurements can be extrapolated to analysis and measurement of metal layer characteristics of other components (e.g. arithmetic logic units, registers, etc.) of a semiconductor chip in addition to the ring oscillators.

In one embodiment, the analysis includes determining a delay associated with a dominate via resistance and the delay can be correlated to a process variation. The analysis can include deconvolving the via resistance, flaws, etc. In one embodiment, characteristics of a device are analyzed based upon the transition delay time. It is appreciated that a variety of characteristics can be analyzed. In one embodiment results from a ring oscillator including a resistance dominated via are compared to a spice simulation of the circuit. If the actual physical implementation is running faster then it is an indication the resistance is higher than expected. In one embodiment, a dominant characteristic ring oscillator system can be utilized to identify catastrophic failures (e.g., an open or infinite resistance, a excessive delay on a critical path, etc.). In one embodiment, a dominant characteristic ring oscillator system can be utilized to identify soft failures (e.g., a particular resistance, a delay on a non-critical path, etc.).

In one embodiment, analysis results indicates various conclusions. The systematic reticle level pattern is definitely mask/litho related. Slight via 2 resistance increase indicates a M2/Via 2 misalignment issue. The M2/Via2 misalignment issue in turn indicates a significant increase via 2 failure rate. The top dies parts that pass CP/Ft may have undetectable high resistance vias that impact system speed. In one exemplary implementation, the analysis facilitates reducing or avoiding wasted time figuring out speed issue when chances are significantly higher that process can be a source of the problems. In one embodiment, analysis can be direct to lithographic lens issues by making target component sensitive to lithographic pattern issues (e.g., trifoil, de-focus, chroma, higher order aberrations, etc.).

Characteristic dominated ring oscillator systems and methods facilitate convenient and efficient analysis of various characteristics and features. In one embodiment, characteristic dominated ring oscillator systems and methods can enable measurement of information associated with the various characteristics and features utilizing fewer resources (e.g., 100 - 200 vias, 1000 - 2000 vias, etc.) than conventional approaches (e.g., 500,000 vias, 1,000,000 vias, etc.). In one exemplary implementation, the information is retrieved in convenient digital format. In one embodiment, greater amounts of information at greater granularity can be retrieved at a lower cost and utilizing fewer resources than a traditional approach (e.g., more measurement "points" can be included on a die, much less die area and resources are occupied, etc.). The increased amount and granularity (e.g., directed to particular area of die, directed to particular process sensitivity, etc.) can be utilized for improved analysis of potential problems.

It is appreciated that a dominant characteristic can be a characteristic that has a detectable impact on signal transition or propagation through a ring oscillator. The dominant characteristic can be dominant in an absolute sense or may be dominant in a relative sense on the detectable impact. In one embodiment, the target component resistance is not more dominant in an absolute sense than a second other component (e.g., inverter, controller, etc.) and if the second other component resistance is not altered, a change in the target component resistance has a dominant or detectable impact on the change in a transition or propagation of a signal transition since the other component resistance is not altered. In one embodiment, where via resistance (e.g., 10 ohms, 100 ohms, etc.) is less than resistance of another component (e.g., 1000 ohms, 3000 ohms, etc.) in an absolute sense, if the via resistance is changed (e.g., 20 ohms, 300 ohms, etc.) and the other component resistance is not changed then the via resistance has a dominant impact on the resulting change in signal transition delay. While the "dominant" characteristic of target components in many of the presented examples (e.g., 121, 122 and 123, etc.) it is appreciated that the "dominant"

characteristic of a target component can include various characteristics (e.g., impedance, capacitance, inductance, etc.).

Presented systems and methods facilitate convenient and efficient analysis. It is appreciated the target components can consume less resources and produce more useful information than conventional approaches. For example, additional components (e.g., vias, contacts, etc.) added in present approaches (e.g., 1000 to 2000, 100 - 200 , etc.) can be significantly less and more efficient then extremely large number of vias (e.g., 500,000, million, etc.) included in some conventional approaches. In one embodiment, components associated with presented systems and methods can be granularly implemented (e.g., consume relatively small die area, placed relative close to die components, etc.). Results from granular implementation can be extrapolated to other components in the die (e.g., fabrication issues, operation issues, etc.). The presented systems and methods also readily provide digital information that can be utilized in various processing analysis.

Figure 15 is a block diagram of an exemplary metal analysis system 1500 in accordance with one embodiment of the present invention. Metal analysis system 1500 includes analysis component 1501, dominate characteristic ring oscillator 1502, dominate characteristic ring oscillator 1503, dominate characteristic ring oscillator 1504, and dominate characteristic ring oscillator 1505. Dominate characteristic ring oscillators 1502, 1503, 1504 and 1505 are operable to oscillate signal transitions, wherein transition timing and delays are impacted by a dominate characteristic of the respective dominate characteristic ring oscillators 1502, 1503, 1504 and 1505. It is appreciated that the dominate characteristic can include a variety of different characteristics (e.g., high channel resistance, low channel resistance, high coupling capacitance, low coupling capacitance, etc.). Analysis component 1501 is operable to analyze indications associated with the respective dominate characteristics. In one embodiment, analysis component 1501 is operable to analyze a frequency and delays in transitions of respective signals forwarded from the dominate characteristic ring oscillators. In one exemplary implementation, analysis component 101 is operable to correlate delays in transitions of respective signals forwarded from the dominate characteristic ring oscillators to coupling resistance and coupling capacitance included in at least one of the dominate characteristic ring oscillators.

In order not to obfuscate the invention, much of the detailed description is directed to exemplary embodiments that include a transistor channel resistance (e.g. of a driving inverter gate, etc.) and coupling metal layer wires. More generally, an inversion stage includes a role resistance component and a coupling component. In one exemplary implementation, the role resistance component includes a transistor channel and a coupling component includes a metal layer coupling (e.g., wire, line, trace, etc.). A role resistance component is any type of component that can be utilized to influence the comparative impact of a coupling component resistance on a transition timing or delay. The role resistance component can have a resistance that has a greater or lesser comparative impact or influencing "role" on a signal transition delay than a coupling component resistance. In one embodiment, the greater or higher the resistance of the role resistance component as compared to the resistance of the coupling component, the greater or more proportionally significant the impact of the role resistance component on the delay of a transition as compared to a coupling component resistance.

Figure 16 is a block diagram of an exemplary dominate characteristic ring oscillator 1600 in accordance with one embodiment of the present invention. In one embodiment, a dominate characteristic ring oscillator similar to dominate characteristic ring oscillator 1600 can be utilized as a dominate characteristic ring oscillator (e.g., 1502, 1503, 1504, 1505, etc.) in dominate characteristic analysis system 1500. Dominate characteristic ring oscillator 1600 includes inversion stage 1610, inversion stage 1620, inversion stage 1630, control component 1640 and output 1675. The inversion stages are operable to cause at least one respective inversion transition in a signal. The respective inversion transition in the signal is impacted by the respective dominate characteristic of the inversion stages. In one embodiment, the dominate characteristic can impact timing or delay of a signal transition through an inversion stage. It is appreciated the dominate characteristic can include a variety of different characteristics (e.g., a high channel resistance, low channel resistance, high coupling capacitance, low coupling capacitance, etc.). Control component 1640 is operable to control a state of the signal. Output 1675 is operable to output a signal.

Inversion stage 1610 includes role resistance component 1611 and coupling component 1612. Inversion stage 1620 includes role resistance component 1621 and coupling component 1622. Inversion stage 1630 includes role resistance component 1631 and coupling component 1632. In one embodiment, the role resistance components include inverters that are operable to cause at least one respective inversion transition in a signal and the coupling components are operable to convey the respective signal transitions to another stage. In one embodiment, the inverters are configured to include at least one transistor (e.g., an inverter driver gate, pull-up transistor, etc.) that has a dominant channel resistance characteristic. In one embodiment, the coupling components are configured to have a dominant coupling capacitance characteristic (e.g., relatively high coupling capacitance, relatively low coupling capacitance, etc). The respective inversion transition in the signal is impacted by the respective dominate characteristic of the inversion stages. In one embodiment, the dominate characteristic (e.g., channel resistance, wire resistance, coupling capacitance, etc.) can impact timing or delay of a signal transition through an inversion stage.

Again, much of the detailed description is directed to exemplary role resistant components that include a transistor channel resistance of an driving inverter gate while coupling components are described as metal layer wires. It is appreciated that a variety of components can be utilized as role resistance components (e.g., any type of component that can be utilized to influence the comparative impact of a coupling component resistance on a transition timing or delay, etc.) and any type of coupling component (e.g., metal layer wire, trace, line etc.). In one embodiment, the greater the resistance of the role resistance component, the lesser the comparative respective impact of a coupling component resistance on a signal transition delay. In one embodiment, a plurality of metal sensitive ring oscillators are included in a metal layer. In one embodiment, a four ring oscillator strategy is employed for each individual metal layer. In one embodiment, a four ring oscillator configuration is included in each individual metal layer. The four ring oscillators can be organized into two groups or sets each with two ring oscillators. The first set can include ring oscillators that have a high channel resistance relative to a coupling or wire resistance. The second set can have a low channel resistance relative to a coupling or wire resistance. In one embodiment, within each set, there are two ring oscillators, a first ring oscillator with a high coupling capacitance relative to another inversion stage or coupling component in another ring oscillator, and a second ring oscillator with a low coupling capacitance relative to another inversion stage or coupling component in another ring oscillator. In one embodiment, examination and analysis of ring oscillator features and characteristics includes indications of both wire capacitance and wire resistance.

Figure 17 is a block diagram of exemplary dominate characteristic analysis system 1700 in accordance with one embodiment of the present invention. In one embodiment, dominate characteristic analysis system 1700 is similar to dominate characteristic analysis system 1600. Dominate characteristic analysis system 1700 includes analysis component 1710, dominate characteristic ring oscillator 1720, dominate characteristic ring oscillator 1730, dominate characteristic ring oscillator 1740, and dominate characteristic ring oscillator 350. Analysis component 1710 includes counter 311, counter 312, counter 313 and counter 314 and analysis component 350. Counter 311 is coupled to dominate ring oscillator 320, counter 312 is coupled to dominate ring oscillator 330, counter 313 is coupled to dominate ring oscillator 1740 and counter 314 is coupled to dominate ring oscillator 1750.

Dominate characteristic ring oscillator 1720 includes inversion stages 321, 322 and 323, and controller stage 324. In one embodiment, a dominate characteristic ring oscillator forwards a signal that has been subject to transition delays impacted by relatively high channel resistance and high coupling capacitance. In one exemplary implementation, each respective inversion stage (e.g., 321, 322 and 323) includes a respective high channel resistance inverter (e.g., 361, 363 and 365) and respective high capacitance dominate characteristic coupling component (e.g., 362, 364 and 366). Controller stage 324 includes NAND gate 367.

Dominate characteristic ring oscillator 1730 includes inversion stages 331, 332, 333, and controller 334. In one embodiment, a dominate characteristic ring oscillator forwards a signal that has been subject to transition delays impacted by relatively high channel resistance and low coupling capacitance. In one exemplary implementation, each respective inversion stage (e.g., 331, 332 and 333) includes a respective high channel resistance inverter (e.g., 371, 373 and 375) and respective low capacitance dominate characteristic coupling component (e.g., 372, 374 and 376). Controller stage 334 includes NAND gate 377.

Dominate characteristic ring oscillator 1740 includes inversion stages 341, 342, 343, and controller 344. In one embodiment, a dominate characteristic ring oscillator forwards a signal that has been subject to transition delays impacted by relatively low channel resistance and high coupling capacitance. In one exemplary implementation, each respective inversion stage (e.g., 341, 342 and 343) includes a respective high channel resistance inverter (e.g., 381, 383 and 385) and respective low capacitance dominate characteristic coupling component (e.g., 382, 384 and 386). Controller stage 344 includes NAND gate 387.

Dominate characteristic ring oscillator 1750 includes inversion stages 351, 352, 353, and controller 354. In one embodiment, dominate characteristic ring oscillator forwards a signal that has been subject to transition delays impacted by relatively low channel resistance and low coupling capacitance. In one exemplary implementation, each respective inversion stage (e.g., 351, 352 and 353) includes a respective low channel resistance inverter (e.g., 391, 393 and 395) and respective low capacitance dominate characteristic coupling component (e.g., 372, 374 and 376). Controller stage 354 includes NAND gate 397. Each counter (e.g., 311, 312, 313 and 341) counts transitions in a respective signal from each respective dominate ring oscillator (e.g., 320, 330, 340 and 350). Counter 311, counter 312, counter 313 and counter 314 are coupled to analysis component 350.

Analysis component 1750 analyzes the count information to determine the impact of the dominate characteristic of the respective dominate characteristic ring oscillators.

Figure 18 is a flow chart of exemplary metal analysis method 1800 in accordance with one embodiment of the present invention.

In block 1810, a dominate characteristic ring oscillation process is performed. In one embodiment, the dominate characteristic ring oscillation process facilitates segregation of coupling capacitance and resistance. In one embodiment, the dominant characteristic ring oscillation process includes pull ups and pull downs of a signal wherein at least one transition is impacted by the dominate characteristic. In one exemplary implementation, the dominate characteristic ring oscillation process includes transitions between a logical 1 state to a logical 0 state. A signal in a first state is received and a signal in a second state is output, wherein a delay between receiving the first logical state signal and outputting the second logical state signal is impacted by a dominate characteristic. In one embodiment, the second logic state is the opposite or inverse of the first logic state. In one embodiment, a resistance current increases or makes the delay longer than would otherwise take if the resistance current was not impacting the transition.

In block 1820, an analysis process is performed. In one embodiment, results of the dominate characteristic ring oscillation process are analyzed. It is appreciated that a variety of different analysis can be performed. Insight into metal capacitance and resistance separately for each metal layer can be used to improve process as well as improve process modeling. Significant deviation in any metal layer can be fed back to the process team. Correlation between resistance and capacitance of the various metal layers can be fed back into extraction tool tech files and process margins in timing runs. As capacitance and resistance are segregated, they can be used as a basis for

extrapolating to a 3D layout. Getting this information from ring oscillators enables high volume data collection across many production lots, which facilitates more accurate statistical analysis of process drift.

In one embodiment, the analysis includes determining a delay associated with a dominate characteristic of the dominate characteristic ring oscillation process. The delay can be correlated to a process variation. The analysis can include deconvolving transistor speed, deconvolving metal resistance and deconvolving metal capacitance. In one exemplary implementation, analyzing includes: examining a high channel resistance ring oscillator where the metal resistance plays a relatively very small role in a delay; identifying an indication of capacitance change; combining an examination of a low channel resistance ring oscillator with results of the high channel resistance ring oscillator; and determining metal resistance difference between dense and sparse lines.

Figure 19 is a flow chart of exemplary dominate characteristic ring oscillation process 1900 in accordance with one embodiment of the present invention. In one embodiment, a signal is transitioned through inversion stages.

[001] In block 1910, a high channel resistance low coupling capacitance process is performed. In one embodiment, the high channel resistance and low capacitance are in an inversion stage. In one exemplary implementation, the high channel resistance is high with respect to or compared to a coupling resistance of the inversion stage. The low coupling capacitance is low with respect to coupling capacitance of another inversion stage.

In block 1920, a high channel resistance high coupling capacitance process is performed. In one embodiment, the high channel resistance and high capacitance are in an inversion stage. In one exemplary implementation, the high channel resistance is high with respect to or compared to a coupling resistance of the inversion stage and the low coupling capacitance is low with respect to coupling capacitance of another inversion stage. In block 1930, a low channel resistance low coupling capacitance process is performed. In one embodiment, the high channel resistance and low capacitance are in an inversion stage. In one exemplary implementation, the high channel resistance is a high with respect to or compared to a coupling resistance of the inversion stage and the low coupling capacitance is low with respect to coupling capacitance of another inversion stage.

In block 1940, a low channel resistance high coupling capacitance process is performed. In one embodiment, the high channel resistance and high capacitance are in an inversion stage. In one exemplary implementation, the high channel resistance is high with respect to or compared to a coupling or wire resistance of the inversion stage and the low coupling capacitance is low with respect to coupling capacitance of another inversion stage.

Figure 20 is a flow chart of exemplary analysis process 2000 in accordance with one embodiment of the present invention. In one exemplary implementation, analysis process 2000 is similar to the analysis process of block 1820. In one exemplary implementation, analysis process 2000 is similar to the analysis performed by analysis component 1501. With reference back to Figure 15, it is appreciated that analysis component 1501 can include a variety of implementations. The analysis component 1501 can include components on chip with the dominate characteristic oscillating rings, components off chip from the dominate characteristic oscillating rings, and combination of components on and off chip. It is also appreciated that the analysis component 1501 can perform a variety of different analysis. In one exemplary implementation, the analysis can include transition delays, determination of channel resistance,

determination of coupling capacitance, manufacturing process compliance and defects, etc.

In block 2010, an indication associated with a dominate characteristic is received. In one embodiment, the indication includes transitions in a signal in which at least one transition delay is impacted by a dominate characteristic. In block 2020, a transition delay time is determined, wherein the transition delay time is impacted by a dominate characteristic. It is appreciated that a transition delay can be impacted by a variety of dominate characteristics (e.g., high channel resistance, low channel resistance, high coupling capacitance, low coupling capacitance, etc.).

In block 2030, characteristics of a device are analyzed based upon the transition delay time. It is appreciated that a variety of characteristics can be analyzed. In one embodiment, analysis of metal layer characteristics is performed. In one exemplary implementation, the transition delay times can be utilized to examine fabrication processes and device operations. The transition delays can be utilized to extrapolate resistance measurements and coupling capacitance measurements for both components included in an oscillating ring and other components of a semiconductor chip. The other components can include components in an area of a semiconductor chip close to components or with similar characteristics of components of a metal analysis system (e.g., 1500, 1600, 1700, etc.). In one exemplary implementation, measurements associated with a dominate characteristic (e.g., line metal resistance, channel metal resistance, line coupling capacitance, etc.) of ring oscillators is extrapolated based upon transition delays in the ring oscillators and the measurements are extrapolated to analysis and measurement of metal layer characteristics of other components (e.g. arithmetic logic units, registers, etc.) of a semiconductor chip in addition to the ring oscillators.

In one embodiment, the coupling components are coupling lines (e.g., metal lines, etc.). The coupling lines can be spaced to have different capacitive characteristics. Figure 21 is a block diagram of an exemplary coupling component 2100 in accordance with one embodiment of the present invention. In one embodiment, coupling component 2100 is similar to coupling components 1612, 1622, and 1623. Coupling component 2100 includes lines 2110, 2120, 2130, 2140 that are configured with respective spaces or distances 2151, 2152 and 2153 between the lines. In one embodiment, coupling component 2100 has a relatively high coupling capacitance dominate characteristic. In one exemplary implementation, the spaces or distance between the lines is kept close to a minimum. In one exemplary implementation, the spaces or distance between the lines is approximately close to the width of the respective lines. In one embodiment, wire capacitance gets multiplied by Miller effect as adjacent wires are driven to opposite voltages approximately simultaneously. In one exemplary implementation each line is approximately 50 nanaometers wide and each space is approximately 50 nanometers wide.

Figure 22 is a block diagram of an exemplary coupling component 2200 in accordance with one embodiment of the present invention. In one embodiment, coupling component 2200 is similar to coupling components 212, 222, and 223. Coupling component 2200 includes lines 2210, 2220, 2230, 2240 that are configured with respective spaces or distances 2251, 2252 and 2253 between the lines. In one embodiment, coupling component 2200 has a low coupling capacitance dominate characteristic. In one exemplary implementation, the coupling spaces are approximately close to the 2 to 3 times the width of respective lines. In one exemplary implementation each line is approximately 50 nanaometers wide and each space is approximately 100 to 150 nanometers wide.

Figure 23 is a block diagram of exemplary transistor 2300 in accordance with one embodiment of the present invention. In one embodiment, transistor 2300 is similar to transistors included in inverters 1611, 1621, and 1621. Transistor 2300 includes source 2310, drain 2320 and gate 2330. In one embodiment, transistor 2300 has a high channel resistance dominate characteristic. In one embodiment, gate 2330 is single wide gate. In one exemplary implementation, gate 2330 is approximately 250 nanaometers wide. In one exemplary implementation, the transistor channel resistance is significantly larger than the metal wire resistance. In one exemplary implementation the transistor channel length is long. In one exemplary implementation there is a small width/length ratio and it is less sensitive to random variation.

Figure 24 is a block diagram of exemplary transistor 2400 in accordance with one embodiment of the present invention. In one embodiment, transistor 2400 is similar to transistors included in inverters 1611, 1621, and 1621. Transistor 2400 includes a plurality of source regions (e.g., 2411, 2412, 2413, 2414, and 2415), a plurality of drain regions (e.g., 2421, 2422, 2423, 2424 and 2425) and a plurality of gate regions (e.g., 2431, 2432, 2433, 2434, 2435, 2436, 2437, 2438 and 2439). In one embodiment, transistor 2400 has a low channel resistance dominate characteristic. In one exemplary implementation, the transistor channel resistance is significantly smaller than the metal wire resistance. In one exemplary implementation the transistor channel length is short with a lot of fingers. In one exemplary implementation there is a big width/length ratio and the multiple fingers facilitate reduction in random variation. In one exemplary implementation, the gates are approximately 50 nanaometers wide.

In one embodiment, a low drive strength ring oscillator includes a high transistor channel resistance and a signal transition delay is dominated by the transistor channel resistance and wire coupling capacitance. In one exemplary implementation, the coupling capacitance is varied significantly and the wire resistance plays a much less significant role in impacting the signal transition or inversion timing or delay. In one exemplary implementation, the configuration can be utilized to figure out wire coupling capacitance.

In one embodiment, a high drive strength ring oscillator includes a low transistor channel resistance the delay and a transition is dominated by both the transistor channel resistance and wire coupling capacitance. There can be wire metal loads, one with high capacitance and one with low capacitance. In one exemplary implementation, the coupling capacitance is varied significantly but the resistance varies a little (e.g. due to layout effects). The previously extracted capacitance is utilized to calculate the wire resistance. In one embodiment, channel resistance is modulated by modifying the driving inverter gate. A high drive strength gate is used for a low channel resistance driver. A custom designed long channel length gate is used as a high channel resistance gate. The channel length can be designed to increase channel resistance significantly higher than the metal resistance (e.g., a 10 times to 1000 times larger or more, etc.). Random error due to variation "polluted" results can also be considered in channel length design. In one embodiment, it is important to use a long channel inverter as small drive strength min-size devices are very susceptible to random dopant fluctuations. In one exemplary implementation, since the high channel resistance ring oscillator (RO) is going to be transistor dominated, it is important to minimize random error. The high channel resistance RO can be very sensitive to the coupling capacitance of the wire. The coupling capacitance of the wires can be controlled by layout design. Minimum pitch lines can have increased or maximized capacitance and higher space metal lines can have decreased or minimized capacitance. Based on these four data points it is possible to deconvolve transistor speed, metal resistance, and metal capacitance.

In one embodiment, the capacitance is modified. In one exemplary implementation, only the capacitance is modified. This can be done utilizing a coupling capacitance source that is altered to change with or against the signal being driven. The resistance is fixed as it is the same wire, but the capacitance is changed. Figure 25 is a block diagram of an exemplary capacitance modification configuration 1100 in accordance with one embodiment of the present invention. Coupling capacitance modification configuration 2500 includes inverters 2521 and 2522, buffers 2511, 2512 and 2513, MUX 2530, metal coupling line 2540, control component 2570 and signal coupling line 2550. Inverter 2521 is coupled to inverter 2521, buffer 2511 and buffer 2512 which is coupled to buffer 2513. MUX 2530 is coupled to inverter 2521 , buffer 2511 , VDD signal 2581 and select signal 2582. Metal coupling line 2540 is coupled to MUX 2530 and control component 2570. Signal coupling line 2550 is coupled to buffer 2513.

The components of coupling capacitance modification configuration 2500 cooperatively operate to modify the coupling capacitance characteristics. In one embodiment, the coupling capacitance is programmably modified while the resistance is fixed. In one embodiment, coupling capacitance modification configuration 2500 is included in a system similar to system 200. In one exemplary implementation inverter 2522 is similar to an inverter in a role resistance component (e.g., 2611, 1621, 1631, etc.) and signal coupling line 2550 in included in a coupling component (e.g., 1612, 1622, etc.) and communicatively couples a signal between role resistance components. The MUX 2530 forwards a signal to metal coupling line 2540 in accordance with selection signal 2582. In one embodiment, there are three programmable states including best case, neutral case and worst case. In the best case state, the coupling metal line 2540 is driven with a signal in the same direction or value as a signal on signal coupling line 2550. In the neutral case state, coupling metal line 1140 is driven with a fixed and unchanging value. In one exemplary implementation, MUX 2530 forwards the VDD signal 2581 to the coupling metal line 2540 in a neutral case state. In the worst case state, the coupling metal line 1140 is driven with a signal in the opposite direction or value as a signal on signal coupling line 2550. In one embodiment, buffers 2512 and 2513 introduce a balance delay to achieve substantially simultaneous switching of coupling metal line 2540 and signal coupling line 2550. Control component 2570 can control the output.

The described systems and methods can facilitate examination of device parameters including analysis of relatively dominant characteristic impacts on delays. In one embodiment, at least some coupling components (e.g., metal layer wires, traces, lines, etc.) have a relatively dominate impact on delays and the delay is in part a function of both capacitance and resistance of the coupling component. In one embodiment, a system comprises a plurality of dominate characteristic oscillating rings, wherein each respective one of the plurality of dominate characteristic oscillating rings includes a respective dominate characteristic based upon: a coupling resistance relative to a channel resistance; and a coupling capacitance relative to a coupling capacitance of another respective one of the plurality of dominate characteristic oscillating rings. The system can also include an analysis component operable to analyze an indication of the respective dominate characteristic (e.g., metal wire capacitance, metal wire resistance, etc.) associated with each respective one of the plurality of dominate characteristic oscillating rings. Additional analysis can be performed correlating the dominate characteristic delay impact results with device fabrication and device operations.

1. A system comprising:

a plurality of dominate characteristic oscillating rings, wherein each respective one of the plurality of dominate characteristic oscillating rings includes at least one dominate characteristic inversion stage with a respective dominate characteristic based upon:

a coupling resistance relative to a channel resistance; and a coupling capacitance relative to a coupling capacitance of another respective one of the plurality of dominate characteristic oscillating rings; and an analysis component operable to analyze an indication of the respective dominate characteristic associated with each respective one of the plurality of dominate characteristic oscillating rings.

2. A ring oscillator of Concept 1 wherein the dominate characteristic includes: a high channel resistance relative to a coupling resistance of the at least one dominate characteristic inversion stage; and

a low coupling capacitance relative to coupling capacitance of another dominate characteristic inversion stage in another one of the plurality of dominate characteristic oscillating rings.

3. A ring oscillator of Concept 1 wherein the dominate characteristic includes: a high channel resistance relative to a coupling resistance of the at least one dominate characteristic inversion stage; and

a high coupling capacitance relative to coupling capacitance of another dominate characteristic inversion stage in another one of the plurality of dominate characteristic oscillating rings.

4. A ring oscillator of Concept 1 wherein the dominate characteristic includes: a low channel resistance relative to a coupling resistance of the at least one dominate characteristic inversion stage; and

5. A ring oscillator of Concept 1 wherein the dominate characteristic includes: a low channel resistance relative to a coupling resistance of the at least one dominate characteristic inversion stage; and a low coupling capacitance relative to coupling capacitance of another dominate characteristic inversion stage in another one of the plurality of dominate characteristic oscillating rings.

6. The system of Concept 1 wherein the analyzing includes identifying process variations based upon the indication of the dominate characteristic.

7. A method comprising:

performing a dominate characteristic ring oscillation process; and

analyzing results of the dominate characteristic ring oscillation process.

8. The method of Concept 7 wherein the analysis includes determining a delay associated with a dominate characteristic of dominate characteristic ring oscillation process.

9. The method of Concept 7 wherein the analysis includes correlating a delay associated with at least one of the dominate characteristic oscillation rings to a process variation.

10. The method of Concept 7 wherein the analysis includes deconvolving transistor speed.

11. The method of Concept 7 wherein the analysis includes deconvolving metal resistance.

12. The method of Concept 7 wherein the analysis includes deconvolving metal capacitance.

13. The method of Concept 7 wherein the analyzing comprises:

examining a high channel resistance ring oscillator where metal resistance plays a relatively very small role in delay;

identifying an indication of capacitance change is identified; combining an examination of a low channel resistance ring oscillator with results of the high channel resistance ring oscillator; and

determining the metal resistance difference between dense and sparse lines.

14. A ring oscillator comprising :

at least one inversion stage including an inverter and coupling component, wherein the inversion stage includes a dominate characteristic that impacts a transition of a signal through a ring path; and

an output operable to output an indication of the impact the dominate characteristic has on the transition of the signal through the ring path.

15. A ring oscillator of Concept 14 wherein the dominate characteristic includes: a high channel resistance relative to a coupling resistance of the at least one inversion stage; and

and a high coupling capacitance relative to another inversion stage in another ring oscillator.

16. A ring oscillator of Concept 14 wherein the dominate characteristic includes: a high channel resistance relative to a coupling resistance of the at least one inversion stage; and

and a low coupling capacitance relative to another inversion stage in another ring oscillator.

17. A ring oscillator of Concept 14 wherein the dominate characteristic includes: a low channel resistance relative to a coupling resistance of the at least one inversion stage; and

18. A ring oscillator of Concept 14 wherein the dominate characteristic includes: a low channel resistance relative to a coupling resistance of the at least one inversion stage; and and a low coupling capacitance relative to another inversion stage in another ring oscillator.

19. The ring oscillator of Concept 14 wherein said output is coupled to an analysis component.

20. The ring oscillator of Concept 14 further comprising a control component coupled to the ring path to control a state of the signal.

Portions of the detailed description are presented and discussed in terms of a method. Although steps and sequencing thereof are disclosed in figures herein describing the operations of this method, such steps and sequencing are exemplary. Embodiments are well suited to performing various other steps or variations of the steps recited in the flowchart of the figure herein, and in a sequence other than that depicted and described herein.

Some portions of the detailed description are presented in terms of procedures, steps, logic blocks, processing, and other symbolic representations of operations on data bits that can be performed within a computer memory. These descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. A procedure, computer-executed step, logic block, process, etc., is here, and generally, conceived to be a self-consistent sequence of steps or instructions leading to a desired result. The steps include physical manipulations of physical quantities. Usually, though not necessarily, these quantities take the form of electrical, magnetic, optical or quantum signals capable of being stored, transferred, combined, compared, and otherwise manipulated in a computer system. It has proven convenient at times, principally for reasons of common usage, to refer to these signals as bits, values, elements, symbols, characters, terms, numbers, or the like.

It should be borne in mind, however, that all of these and similar terms are associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise as apparent from the following discussions, it is appreciated that throughout the present application, discussions utilizing terms such as "processing", "computing", "calculating", "determining", "displaying" or the like, refer to the action and processes of a computer system, or similar processing device (e.g., an electrical, optical, or quantum, computing device) , that manipulates and transforms data represented as physical (e.g., electronic) quantities. The terms refer to actions and processes of the processing devices that manipulate or transform physical quantities within a computer system's component (e.g., registers, memories, other such information storage, transmission or display devices, etc.) into other data similarly represented as physical quantities within other components

Some embodiments may be described in the general context of computer-executable instructions, such as program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects,

components, data structures, etc., that perform particular tasks or implement particular abstract data types. Typically the functionality of the program modules may be combined or distributed as desired in various embodiments. Computing devices can include at least some form of computer readable media.

Computer readable media can be any available media that can be accessed by a computing device. By way of example, and not limitation, computer readable medium may comprise computer storage media and communication media. Computer storage media includes volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules, or other data. Computer storage media includes, but is not limited to, RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, digital versatile discs (DVD) or other optical storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to store the desired information and which can be accessed by a computing device. Communication media typically embodies computer readable instructions, data structures, program modules, or other data in modulated data signals such as carrier waves or other transport mechanism and includes any information delivery media. The term

"modulated data signal" means a signal that has one or more of its characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media includes wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, RF, infrared, and other wireless media. Combinations of any of the above should also be included within the scope of computer readable media.

The foregoing descriptions of specific embodiments of the present invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the Claims appended hereto and their equivalents.

Claims

CLAIMS What is claimed is:

1. A ring oscillator comprising:

at least one inversion stage operable to cause a signal transition; wherein said inverting stage is coupled to another component through a via layer in which a resistance due to characteristics of the via layer coupling has a relatively significant impact on a transition of a signal through a ring path; and

an output component for outputting an indication of the impact the via resistance has on the signal transition of the signal through the ring oscillator.

2. A ring oscillator of Claim 1 in which the coupling through the via layer includes a first horizontal metal layer component at one level and a second horizontal metal layer component at another level and a vertical component coupling the first horizontal metal layer component at one level and a second horizontal metal layer at another level.

3. A ring oscillator of Claim 2 wherein the first horizontal metal layer component, the second horizontal metal layer component and the vertical component are configured to form a reduced coupling enclosure area for increased sensitivity to misalignment.

4. A ring oscillator of Claim 2 wherein the first horizontal metal layer component, the second horizontal metal layer component and the vertical component are configured to form an enlarged coupling enclosure area for reduced sensitivity to misalignment.

5. A ring oscillator of Claim 2 wherein the vertical component is wide compared to the first horizontal component and second horizontal component.

6. A ring oscillator of Claim 2 wherein the vertical component is narrow compared to the first horizontal component and second horizontal component.

7. A ring oscillator of Claim 1 wherein the via resistance is significantly higher than the channel resistance of a driving transistor.

8. A method comprising:

performing a dominant characteristic ring oscillation process; and

analyzing results of the dominant ring oscillation process.

9. The method of Claim 8 wherein the analysis includes determining a delay associated with the via resistance characteristic of dominant via resistance ring oscillation process.

10. The method of Claim 8 wherein the analysis includes correlating a delay associated with at least one of the dominant via resistance characteristic oscillation rings to a process variation.

11. The method of Claim 8 wherein the analysis includes deconvolving transistor speed.

12. The method of Claim 8 wherein the analysis includes deconvolving metal resistance.

13. The method of Claim 8 wherein the analyzing comprises:

examining large enclosure ring oscillator where via resistance plays a relatively very small role in delay;

examining small enclosure ring oscillator where via resistance plays a relatively very large role in delay; and

determining the via resistance difference due to via discontinuity.

14. A ring oscillator comprising :

at least one inversion stage operable to cause a signal transition;

a target component that has an increased comparative impact or influence on a signal transition propagation in the ring oscillator; and an output component for outputting an indication of the impact the target component has on the signal transition.

15. A ring oscillator of Claim 14 wherein the target component includes a plurality of vias from one metal layer to another metal layer.

16. A ring oscillator of Claim 15 wherein the plurality of vias from one metal layer to another metal layer are configured in a cell.

17. A ring oscillator of Claim 14 wherein the vias corresponds to a via layer.

18. The ring oscillator of Claim 14 wherein the output is coupled to an analysis component.

19. A ring oscillator of Claim 14 wherein the analysis component can include correlation of the via resistance into a wafer variations and generate a wafer map.

20. The ring oscillator of Claim 14 further comprising a control component coupled to the ring path to control a state of the signal.