This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2012-274747, filed on Dec. 17, 2012, the entire contents of which are incorporated herein by reference.
The embodiments discussed herein are related to a capacitive element, a capacitor array, and an A/D converter.
In recent years, A/D converters are broadly utilized in various fields. More specifically, a successive approximation A/D converter and a delta-sigma A/D converter are known as A/D converters with relatively high resolution. Such A/D converters include a switched-capacitor circuit, for example, and are widely used in the form of CMOS (Complementary Metal Oxide Semiconductor) integrated circuit.
As performance indexes of an A/D converter, there are linearity, an offset, and a gain error, for example. However, the advantage in the conversion characteristic of an A/D converter is largely under the control of a matching, the voltage dependence or the like of a capacitive element in many cases. Therefore, in order to realize an A/D converter with high conversion accuracy, it is preferred to apply capacitive elements with good characteristics.
Such a capacitive element with good characteristics is not limited to be applied to an A/D converter, but, for example, it may be broadly applied also to various electronic circuits including a circuit for measuring instruments.
[About Successive Approximation A/D Converter]
First, a successive approximation A/D converter will be illustrated. A successive approximation A/D converter includes an internal D/A converter (Digital-to-Analog Converter: capacitor DAC), a comparator, and a digital circuit for a successive approximation control.
The successive approximation A/D converter obtains an A/D conversion result by sampling an input analog voltage, comparing the input analog voltage with an output voltage of the capacitor DAC, and searching an output of the capacitor DAC where the two voltages match most closely.
The differential nonlinearity (DNL) of the successive approximation A/D converter is decided according to the matching of the capacitive elements included in the capacitor DAC. Then, when the matching of the capacitive elements is inferior, a code loss, which lacks a part of staircase-shaped transfer characteristic, occurs.
Moreover, the integral nonlinearity (INL) of the successive approximation A/D converter is decided according to the voltage dependence of the capacitive elements included in the capacitor DAC. When the capacitive element includes the voltage dependence, A/D conversion characteristics become nonlinear since a capacitance value changes with voltage across the capacitive element, and this may be a cause of deformation.
Hitherto, self-calibration techniques are proposed as a method of solving a problem of a capacitor mismatch in a successive approximation A/D converter. The self-calibration techniques add a self-calibration circuit including a capacitor DAC to carry out individual calibration after manufacturing (refer to Non-Patent Document 1, for example).
Using the self-calibration techniques eases an influence of the mismatch of capacitive elements to some extent. However, as for the capacitor DAC included in a self-calibration circuit, the larger a mismatch is, the more a circuit scale increases, which causes a circuit area and a manufacturing cost to increase. Accordingly, it remains preferable to have a lower mismatch of capacitive elements.
Moreover, hitherto, a method is proposed by which a capacitor DAC is made to be a differential structure in order to ease an influence of the voltage dependence of a capacitive element, and the voltages applied to the capacitor DAC on positive side and negative side is made to be the same voltage at a step of sampling and a step of comparing (refer to Patent Document 1, for example).
By employing the above-mentioned constitution, it is possible to cancel a first-order term of the voltage dependence of a capacitive element, and to improve the linearity of an A/D conversion. However, since the terms equal to or higher than second order of the voltage dependence of a capacitive element still remain, the linearity of an A/D conversion receives an influence.
[About Delta-Sigma A/D Converter]
Next, a delta-sigma A/D converter will be illustrated. A delta-sigma A/D converter includes a delta sigma modulator and a digital circuit which performs signal processing.
The delta sigma modulator performs a delta-sigma modulation on an input signal, and transfers a digital signal to a latter digital circuit. The digital circuit extracts desired information from a delta-sigma modulated digital signal, and outputs the information as an A/D conversion result.
A typical delta sigma modulator is realized by a switched capacitor, and includes a sampling circuit, an adding and subtracting circuit, an integrating circuit, and a capacitor DAC. To these components, capacitive elements, such as sampling capacitors, reference capacitors, and integral capacitors, are applied (refer to Non-Patent Document 2, for example).
By the way, in a delta-sigma A/D converter with a 1-bit capacitor DAC, the capacitor DAC only outputs a binary, and therefore, the mismatch of capacitive elements does not directly affect linearity.
However, the mismatch between a sampling capacitor and a reference capacitor affects the offset, and in addition, a mismatch among three capacitances of a sampling capacitor, a reference capacitor, and an integral capacitor affects a gain error. In other words, in order to make the offset and the gain error small, it is desirable to increase the relative accuracy of a capacitive element.
In a delta-sigma A/D converter, the voltage dependence of a capacitance value of a capacitive element affects the linearity of an A/D conversion. It is difficult for a delta-sigma A/D converter which includes a typical structure to make voltage applied to a capacitive element the same voltage at a step of sampling and a step of integrating.
Therefore, a delta-sigma A/D converter requires a capacitive element with even lower voltage dependence in comparison with a successive approximation A/D converter with similar degree of resolution.
In this way, it can be understood that the accuracy of an A/D converter highly depends on the characteristics of a capacitive element, as for a successive approximation A/D converter or a delta-sigma A/D converter.
[About Capacitive Element in Integrated Circuit]
There are a parallel plate structure and a comb-shaped structure as structures of a capacitive element used for an A/D converter with relatively high resolution. The electric field between electrodes seen from a wafer cross-section is a lengthwise direction for the parallel plate structure, and a horizontal direction for the comb-shaped structure.
As capacitive elements for the parallel plate structure, PIP (Poly Insulator Poly), MIM (Metal Insulator Metal), and a structure in which wiring layers are arranged in a comb shape are known. The PIP capacitor is the one which has the parallel plate structure and uses polysilicon for an upper electrode and a lower electrode (refer to Patent Document 2, for example).
In an electrode of the PIP capacitor, a high-concentration semiconductor part which is not an ideal conductor remains even though the surface may be silicidated. Therefore, when a potential difference occurs between terminals, a surface potential of the electrode changes slightly.
In a typical manufacturing process, about 50 ppm/v of the first-order voltage coefficient of a capacitance remains, for example. Therefore, when it is applied to the A/D converter with high resolution, linearity may be damaged and there is a possibility to generate a distortion in the conversion result.
Further, since the PIP capacitor is formed of two-layer polysilicon, there is a problem that a manufacturing cost increases. In other words, a typical MOS process uses at least one layer of polysilicon for gate formation of a transistor, but one more layer of polysilicon is to be used only for forming a capacitive element is added, which causes the increase in a manufacturing cost.
On the other hand, a MIM capacitor has a parallel plate structure and has a structure using metal, such as aluminum, for an upper electrode and a lower electrode. As for the MIM capacitor, since the electrode is metal, there is an advantage that the voltage dependence is even smaller than the PIP capacitor, and generally, the capacitance to ground of a lower electrode is small in comparison with the PIP capacitor.
The MIM capacitor can be classified roughly into two kinds, one including the manufacturing process for forming the MIM capacitor, and the other diverting wiring layers. A manufacturing cost increases due to an additional manufacturing process in the former case, whereas an additional cost does not arise in the latter case since it is possible to form the MIM capacitor simultaneously with wiring (refer to Patent Documents 3 and 4, for example).
These capacitive elements having a parallel plate structure is widely used, when wiring material of an integrated circuit is aluminum.
In addition to above-mentioned capacitor structure, there is one of which wiring layer has a comb-shaped structure. In the recent CMOS manufacturing process, miniaturization of elements progresses and copper is used for a wiring material in many cases. The copper wiring has an advantage of lower interconnection resistance in comparison with aluminum interconnection and has high tolerance for an electromigration.
However, since the copper wiring uses a manufacturing process called a damascene, there is a fault that uniform formation becomes difficult when wiring with narrow width and wiring with wide width are mixed. Since a manufacturing process is optimized according to a copper wiring having minimum width, it is difficult to realize a parallel plate capacitance with a relatively large area. Therefore, when wiring material is copper, a comb-shaped structure is usually employed.
In the old days, a wiring pitch of an integrated circuit is large, and it was not realistic to use a horizontal-direction capacitive coupling as a capacitive element using an wiring layer since it causes an increase of an area of silicon.
However, miniaturization of an integrated circuit device has progressed over time, and a wiring pitch has been shrunk. As a result, capacitors with comb-shaped structure have come to be used widely (refer to Patent Documents 5 and 6, and Non-Patent Documents 3 and 4, for example).
Hitherto, a technique has been also proposed by which a planar shield electrode is provided in each of the uppermost layer and the undermost layer of wiring layers which form capacitors, and an electric field between the electrodes of a capacitive element is shielded, thereby preventing the capacitive coupling which is not intended (refer to Patent Documents 7 and 8, for example).
Hitherto, a technique has been also proposed by which wiring electrically connected to a terminal to which high power source potential is applied and wiring electrically connected to a terminal to which low power source potential is applied are formed so that both wirings are adjacent to each other through dielectric and surround an integrated circuit (refer to Patent Document 9, for example).
As mentioned above, it is preferred that the capacitive element to be applied to the A/D converters, such as the successive approximation A/D converter and the delta-sigma A/D converter, has sufficient relative precision and low voltage dependence to achieve a desired resolution. In order to achieve these requirements, any of a PIP capacitor, an MIM capacitor and a comb-shaped capacitor is used.
Among the capacitive elements, the PIP capacitor has a problem of not being able to be formed by a standard logic manufacturing process, requiring additional manufacturing steps, which increases a manufacturing cost. As for the MIM capacitor with parallel plate structure, there is a possibility to reduce a cost by forming electrodes simultaneously with an interconnecting process.
However, a parallel plate structure can be employed only when wiring material is aluminum, and it is difficult to form the structure by a copper wiring process. In other words, a comb-shaped capacitor is usually adopted in a copper wiring process in order to make a high resolution A/D converter without an additional manufacturing process. However, there are various problems in a comb-shaped capacitor as illustrated in detail below.
Patent Document 1: Japanese Laid-open Patent Publication No. 2007-142863
Patent Document 2: U.S. Pat. No. 4,914,546
Patent Document 3: U.S. Pat. No. 5,220,483
Patent Document 4: U.S. Pat. No. 6,066,537
Patent Document 5: U.S. Pat. No. 5,583,359
Patent Document 6: Japanese Laid-open Patent Publication No. 2005-108874
Patent Document 7: U.S. Pat. No. 6,737,698
Patent Document 8: Japanese Laid-open Patent Publication No. 2005-197396
Patent Document 9: Japanese Laid-open Patent Publication No. 2009-278078
Non-Patent Document 1: H. S. Lee et al., “A Self-Calibrating 15 Bit CMOS A/D Converter,” IEEE Journal of Solid-State Circuits Vol. SC-19, No. 6, December 1984
Non-Patent Document 2: B. E. Boser et al., “The deisgn of sigma-delta modulation analog-to-digital converters,” IEEE Journal of Solid-State Circuits, Vol. 23, pp. 1298-1308, December 1988
Non-Patent Document 3: K. T. Christensen, “Design and characterization of vertical mesh capacitors in standard CMOS,” Symp. VLSI Technol., pp. 201-204, 2001
Non-Patent Document 4: Aparicio et al., “Capacity limits and matching properties of integrated capacitors,” IEEE J. Solid-State Circuits, vol. 37, pp. 384-393, 2002
According to an aspect of the embodiments, a capacitive element includes first electrodes and second electrodes that are alternately arranged in a concentric form, and each of the first electrodes and the second electrodes is formed with closed loop form, in at least one wiring layer provided on or above a substrate.
The object and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention.
Before describing embodiments of a capacitive element, a capacitor array, and an A/D converter in detail, examples of a capacitive element, a capacitor array, an A/D converter, and problems thereof will be illustrated in detail with reference to
In other words, as depicted in
In other words, as depicted in
The comb-shaped capacitive element depicted in
Note that, as depicted in
In this way, using the planar shield electrodes as the uppermost layer and the undermost layer of the capacitive element allows a shield of the electric field between the electrodes of the capacitive element, and prevents the capacitive coupling which is not intended.
As mentioned above, it is preferred that the capacitive element to be applied to the A/D converters, such as the successive approximation A/D converter and the delta-sigma A/D converter, have sufficient relative precision and low voltage dependence to achieve a desired resolution. In order to achieve these matters, any of a PIP capacitor, an MIM capacitor and a comb-shaped capacitor is used.
However, the PIP capacitor has a problem of not being able to be formed by a standard logic manufacturing process, requiring additional manufacturing steps, which increases a manufacturing cost. As for the MIM capacitor with parallel plate structure, although there is a possibility to reduce a cost by forming electrodes simultaneously with an interconnecting process, the MIM capacitor has a problem of not being able to be formed by a copper wiring process, for example.
In other words, although the comb-shaped capacitor is usually adopted to make a high resolution A/D converter without an additional manufacturing process in the copper wiring process, the comb-shaped capacitor has problems illustrated in detail below ([first problem] to [third problem]).
[First Problem]
First, the comb-shaped capacitor has a problem that the relative accuracy thereof is inferior in comparison with the PIP capacitor and the MIM capacitor. In other words, the PIP capacitor and the MIM capacitor can be manufactured to be relatively uniform since these capacitors have a simple structure of parallel plates, but the comb-shaped capacitor has a complicated structure and ununiformity is easy to arise, which causes a deterioration of relative accuracy.
The inventors of the present application have noticed that the mismatch in the comb-shaped capacitor is mainly caused by the defects at the ends of the electrodes which form the comb-shaped capacitive element. In other words, as depicted in
There are a number of ends in the electrode of the comb-shaped capacitive element, and it can be considered that the ends of the electrode become defective parts, for example, in the process of trench formation or planarization (CMP: Chemical Mechanical Polishing).
For example, when the degree of the defects which arise at the ends of the electrode is uniform regardless of positions, the relative accuracy of the capacitive element does not deteriorate. However, for example, the defects which arise during the planarization depend on the positions and size of particles of polish, and therefore the degree of defects is random and does not become uniform. Further, the current wiring width is microscopic such as tens of nm, and it is difficult to form the ends uniformly.
[Second Problem]
In addition, the comb-shaped capacitor has a problem that an electric field passing through a substrate changes the potential distribution of the substrate that makes the voltage dependence of the capacitor appear. The voltage dependence of the capacitive element influences the linearity of the A/D converter, and causes a deformation.
In
As depicted in
As a result, the capacitance between the positive (+) electrode and the negative (−) electrode through P-type well region 1 decreases among the capacitive coupling from the positive (+) electrode to the negative (−) electrode. Such decrease of the capacitance is to be observed as the voltage dependence of the capacitive element. It could be also considered that the voltage dependence of the capacitive element occurs by a mechanism similar to the CV characteristics of a gate capacitance of a MOS transistor.
In other words, the part formed by the capacitive element and the bulk section depicted in
Note that the problem of the voltage dependence mentioned above is avoidable, when the undermost layer (METAL1) is made into a shield layer, as is the case with the capacitive element illustrated with reference to
[Third Problem]
Further, the requirements regarding an arrangement of the capacitive elements applied to an A/D converter will be illustrated, and a problem of a conventional arrangement of a comb-shape structured capacitor will be described.
The successive approximation A/D converter depicted in
In
Moreover, the reference mark VIN depicts the input analog voltage and the node for such input (input node), VREF depicts a reference voltage and a node thereof (reference node), and GND depicts a ground potential and a node thereof (ground node).
Further, TOP depicts a top plate of a capacitor D/A converter (DAC), and SW, S0′, S0, S1, S2 and S3 depict switches. CMP depicts a comparator, and SAR depicts a successive approximation control circuit. Note that Cp depicts a parasitic capacitance which is not intended, and will be used in a later illustration.
As depicted in
A capacity ratio of the binary weighted capacitive elements is a prime number, and therefore preparing unit capacitors with a single capacitance value and adjusting the number of parallel connection enable an establishment of a relative relation which is relatively accurate. Note that, since the accuracy of the A/D conversion mainly depends on the relative accuracy of the capacitive elements, it is preferred to arrange the capacitive elements as close as possible each other and it is reasonable to arrange the capacitive elements in an array form.
On the other hand, the switches S0′, S0 to S3 provided at lower ends of capacitive elements are realized by MOS transistors, for example, but it is difficult to arrange the switches in the capacitor array. Therefore, when the switches S0′ and S0 to S3 realized by the MOS transistors are arranged outside the capacitor array, capacitive element and switch is connected by wiring respectively.
Specifically, as depicted in
Further, when the parasitic capacitance (Cp in
However, since the capacitive element with the comb-shape structure mentioned above utilizes a lateral electric field, the parasitic capacitance is easy to arise and there is a possibility of deteriorating the relative relation in the capacitive elements of the capacitor DAC. Note that the above illustration is made mainly for the successive approximation A/D converter, but similar capacitor array may be applied to a delta-sigma A/D converter, for example.
Hereinafter, embodiments of the capacitive element, the capacitor array, and the A/D converter will be illustrated in detail with reference to accompanying drawings.
As depicted in
First, in the capacitive element depicted in
In other words, the capacitive element depicted in
In addition to non-existence of the ends, there is no vertex in the capacitive element depicted in
Although in
Next, as for the capacitive element depicted in
In other words, the capacitive element depicted in
The capacitive element depicted in
Although in
In this way, according to the capacitive element depicted in
As is clear from the comparison between
Thereby, the electric field in the capacitive element prevents the change of the potential structure (for example, generation of depletion region la in
In the capacitive element depicted in
First, as depicted in
Further, as depicted in
Note that, the positive (+) potential is applied to all the electrodes NA, NB and NC of the undermost layer METAL1 in
Further, in
The unit capacitors (for example, the capacitor C0′ and C0 to C3 in
Further, wirings between the capacitors and the outer electrode NA to which the negative (−) potential is applied are shielded by the electrode NC of the ground node G arranged at the wiring layers METAL2 and METAL3. Thereby, the relative relation of the capacitive elements does not deteriorate.
As described above, according to the capacitive element of the present embodiment, it is possible to form the capacitive element suitable for a copper wiring process which is used widely in recent years, to improve the relative accuracy, and to reduce the voltage dependence of the capacitor.
According to the A/D converter of the present embodiment, it is possible to accurately form the capacitor array which is to be applied to the capacitor DAC used inside the A/D converter. As a result, it is possible to achieve the A/D converter with high precision.
Moreover, reference mark N1 depicts the common node (one electrode of each of capacitive elements C0′ and C0: top plate TOP) of the circuit, and N2 and N3 depict the other node (the other electrode: bottom plate) of each of the capacitive elements C0′ and C0.
In the circuit depicted in
In
Since the undermost wiring layer METAL1 is a common node N1, the electric field in the capacitive element does not affect the substrate (silicon substrate). Therefore, the electrical change inside the substrate does not appear as the voltage dependence of the capacitance value.
The outermost circumference of the wiring layers METAL3 and METAL4 and the outermost and the second outermost circumference of the wiring layer METAL2 are fixed to GND potential, and the electric field inside the element is shielded.
In other words, fixing the outermost and the second outermost circumference of the wiring layer METAL2 to GND potential causes, for example, a shield of coupling of the node N2 in the capacitive element C0′ and the common node N1 in the vertical (thickness) direction, and also causes a shield of coupling of the node N3 in the capacitive element C0 and the common node N1 in the lengthwise direction.
Thereby, even when the common node N1 of the capacitive elements C0′ and C0 is connected to the undermost wiring layer METAL1, the parasitic capacitance which is not intended does not arise.
The wiring layer METAL5 is a node which collects the node N2 of the capacitive element C0′, or the node N3 of the capacitive element C0, which prevents capacitive coupling of wiring between the nodes N2 and N3 arranged in the wiring layer METAL6 in the capacitive element.
As illustrated in detail above, by applying the present embodiment, it becomes possible to realize the capacitor array to be included in an A/D converter, without using an electrode with wide width which is difficult to be formed by the current copper wiring process.
In
First, as depicted in
The switches S0′, S0, S1, S2 and S3 are arranged at periphery parts of the plurality of unit capacitors CU (capacitive elements C0′, C0, C1, C2, and C3) arranged in the array form. The comparator CMP and the switch SW are arranged at periphery parts of the plurality of unit capacitors CU (capacitive elements C0′, C0, C1, C2, and C3) arranged in the array form.
In the example of
Moreover, the unit capacitors CU used as the capacitive element C0′ and C0 to C3 are selected so that the unit capacitors are distributed for each capacitive element. Specifically, in
In this way, by considering a selection of the unit capacitors CU used as the capacitive elements C0′ and C0 to C3, it becomes possible to bring the relative relation of the capacitance values of respective capacitive elements close to ideal relation. Note that the arrangement depicted in
Further, as depicted in
In this way, the top plate TOP for each of capacitive elements C0′ and C0 to C3 is formed by merely connecting the electrodes of neighboring unit capacitors, for example, using the wiring of the undermost wiring layer METAL1.
As depicted in
In other words, as depicted in
Further, other node (bottom plate) of capacitive elements C0′, C0, C1, C2 and C3 of which relative capacitance value is determined is connected to corresponding switches S0′ and S0, S1, S2 and S3, for example, by using the uppermost wiring layer METAL6.
Bottom plate wiring (interconnection of switches S0′ and S0 to S3 which correspond with capacitive elements C0′ and C0 to C3) of the capacitor array using the wiring layer METAL6 may be arranged redundantly, and a designated spot may be contacted by a via. Thus, the shape of the uppermost layer of all the capacitive elements can be common, and it becomes possible to set the relative relation of the capacitance values of respective capacitive elements with higher accuracy.
In this way, for example, the successive approximation A/D converter depicted in
The polysilicon layer POLY is a conductive layer used as a gate electrode of a transistor formed on the semiconductor substrate in a general MOS process. In the present modification, the polysilicon layer POLY is used instead of the wiring layer METAL1 which prevents a leak of the electric field to outside in the capacitive element depicted in
According to the modification depicted in
In the modification depicted in
In this way, the shield electrode for preventing the leak of the electric field in the capacitive element to outside can be formed also by the diffusion region or the metallized (silicidated) surface.
According to the modification depicted in
All examples and conditional language provided herein are intended for the pedagogical purposes of aiding the reader in understanding the invention and the concepts contributed by the inventor to further the art, and are not to be construed as limitations to such specifically recited examples and conditions, nor does the organization of such examples in the specification relate to a showing of the superiority and inferiority of the invention. Although one or more embodiments of the present invention have been described in detail, it should be understood that the various changes, substitutions, and alterations could be made hereto without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2012-274747 | Dec 2012 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3060392 | Ciancarelli | Oct 1962 | A |
3289015 | Fitch et al. | Nov 1966 | A |
4914546 | Alter | Apr 1990 | A |
5208725 | Akcasu | May 1993 | A |
5220483 | Scott | Jun 1993 | A |
5583359 | Ng et al. | Dec 1996 | A |
6016019 | Wojewoda | Jan 2000 | A |
6066537 | Poh | May 2000 | A |
6312986 | Hermes | Nov 2001 | B1 |
6737698 | Paul et al. | May 2004 | B1 |
8640529 | Sinha | Feb 2014 | B2 |
8675336 | Lavene et al. | Mar 2014 | B2 |
20060226496 | Juengling | Oct 2006 | A1 |
20070115159 | Tachibana et al. | May 2007 | A1 |
20080173912 | Kumura et al. | Jul 2008 | A1 |
20080237677 | Futatsugi | Oct 2008 | A1 |
20090044627 | Brady | Feb 2009 | A1 |
20090261444 | Yamazaki et al. | Oct 2009 | A1 |
20090288869 | Anderson et al. | Nov 2009 | A1 |
20100117485 | Martin et al. | May 2010 | A1 |
20110303957 | Juengling | Dec 2011 | A1 |
20120013354 | Bowler et al. | Jan 2012 | A1 |
20120056770 | Araki et al. | Mar 2012 | A1 |
Number | Date | Country |
---|---|---|
05-090489 | Apr 1993 | JP |
2005-108874 | Apr 2005 | JP |
2005-197396 | Jul 2005 | JP |
2007-081044 | Mar 2007 | JP |
2007-142863 | Jun 2007 | JP |
2009-278078 | Nov 2009 | JP |
2010-272800 | Dec 2010 | JP |
Entry |
---|
Bernhard E. Boser et al., “The Design of Sigma-Delta Modulation Analog-to-Digital Converters”, IEEE Journal of Solid-State Circuits, Dec. 1988, pp. 1298-1308, vol. 23, No. 6. |
Hae-Seung Lee et al., “A Self-Calibrating 15 Bit CMOS A/D Converter”, IEEE Journal of Solid-State Circuits, Dec. 1984, pp. 813-819, vol. Sc-19, No. 6. |
Kare Tais Christensen, “Design and Characterization of Vertical Mesh Capacitors in Standard CMOS”, 2001 Symposium on VLSI Circuits Digest of Technical Papers, 2001, pp. 201-204. |
Roberto Aparicio et al., “Capacity Limits and Matching Properties of Integrated Capacitors”, IEEE Journal of Solid-State Circuits, Mar. 2002, vol. 37, No. 3. |
Number | Date | Country | |
---|---|---|---|
20140167992 A1 | Jun 2014 | US |