Classifications

• • H—ELECTRICITY
  • H03—ELECTRONIC CIRCUITRY
  • H03H—IMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
  • H03H17/00—Networks using digital techniques
  • H03H17/0009—Time-delay networks
• • H—ELECTRICITY
  • H03—ELECTRONIC CIRCUITRY
  • H03K—PULSE TECHNIQUE
  • H03K5/00—Manipulating of pulses not covered by one of the other main groups of this subclass
  • H03K5/13—Arrangements having a single output and transforming input signals into pulses delivered at desired time intervals
  • H03K5/131—Digitally controlled
• • H—ELECTRICITY
  • H03—ELECTRONIC CIRCUITRY
  • H03H—IMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
  • H03H11/00—Networks using active elements
  • H03H11/02—Multiple-port networks
  • H03H11/26—Time-delay networks
  • H03H11/265—Time-delay networks with adjustable delay
• • H—ELECTRICITY
  • H03—ELECTRONIC CIRCUITRY
  • H03K—PULSE TECHNIQUE
  • H03K5/00—Manipulating of pulses not covered by one of the other main groups of this subclass
  • H03K2005/00013—Delay, i.e. output pulse is delayed after input pulse and pulse length of output pulse is dependent on pulse length of input pulse
  • H03K2005/00019—Variable delay
  • H03K2005/00058—Variable delay controlled by a digital setting
  • H03K2005/00065—Variable delay controlled by a digital setting by current control, e.g. by parallel current control transistors

Definitions

• the present invention relates generally to the field of Structured ASICs. Embodiments of the present invention relate to a circuit for a Structured ASIC.
• the present invention relates generally to an improved Digitally Controlled Delay Line (DCDL) for a Structured ASIC.
• DCDL Digitally Controlled Delay Line
• a Structured ASIC is an ASIC (Application-Specific Integrated Circuit) having some pre-made elements that are manufactured once in a first manufacturing process and kept in inventory, then the elements are interconnected later, or customized by a customer, in a second manufacturing process by masks (mask-programmable) rather than making a circuit all at once as in a traditional ASIC.
• the customization occurs by configuring one or more via layers between metal layers in the ASIC.
• a configurable logic block may be an element of field-programmable gate array (FPGA), structured ASIC devices, and/or other devices. CLBs may be configured, for example, to implement different random logic (from combinational logic, such as NANDs, NORs, or inverters, and/or sequential logic, such as flip-flops or latches).
• FPGA field-programmable gate array
• CLBs may be configured, for example, to implement different random logic (from combinational logic, such as NANDs, NORs, or inverters, and/or sequential logic, such as flip-flops or latches).
• ASICs application-specific integrated circuits
• NRE non-recurring engineering
• ASICs can be broken down further into a full-custom ASIC, a Standard Cell- based ASIC (standard-cell), and a gate array ASIC.
• a field-programmable gate array FPGA
• FPGA field-programmable gate array
• Other non-ASICs include simple and complex PLDs (Programmable Logic Devices), and off-the-shelf small and medium scale IC components (SSI/MSI).
• a full-custom ASIC customizes every layer in an ASIC device, which can have 10 to 15 layers, requiring in a lithography process 10 to 15 masks. Since the customized design of the ASIC occurs at the transistor level, and modern ASICs have tens if not hundreds of millions of transistors, a full-custom ASIC is typically economically feasible only for applications that required millions of units.
• An example of such an application is the cell phone digital modem or a flat panel television video processing device.
• circuits are constructed from predefined logic components known as cells.
• Designers work at the gate level, not the finer transistor level, simplifying the process, and instead of 10-15 layers only 3-5 layers may exist.
• the fab manufacturing the device provides a library of basic building blocks that can be used in the cells, such as basic logic gates, combinational components (and-or- inverter, multiplexer, 1 -bit full adder), and basic memory, such as D-type latch and flip-flop.
• a library of other function blocks such as adder, barrel shifter and random access memory (RAM) may also exist. While the layout of each cell in a standard cell is predetermined, the circuit itself has to be uniquely constructed by connecting all layers to one another and the cells within each layer in a custom manner, which takes time and effort.
• a register is a standard component in an ASIC, and is a group of flip-flops that stores a bit pattern. Registers can hold information from components or hold state between iterations of a clock so that it can be accessed by other components, to allow I/O synchronization, handshaking data between clock domains, pipelining, and the like.
• the level of abstraction is one level higher than a standard cell, in that each building block in a gate array is from an array of predefined cells, known as a base cell, which resembles a logic gate. Since location and type of cell is predetermined, gate-array ASICs can be manufactured in advance in greater quantities and inventoried for use later.
• a circuit is manufactured by customizing the interconnect between these cells, which is done at the metal layer via masks. In gate level ASICs, typically fewer metal layers have to be customized to specify the interconnect required to complete the circuit, which simplifies the manufacturing process.
• a synchronous digital system has a clock distribution network that defines a reference point for moving data within the system.
• a clock distribution network distributes the clock signals from a common point to all the elements in the system that need it.
• clock signals are loaded with a great fanout, travel over comparatively great distances, and operate at the higher speeds than other signals within the synchronous system.
• Clock waveforms must be particularly clean and sharp.
• long global interconnect lines become significantly more resistive as line dimensions are decreased, and is one of the primary reasons for the increasing significance of clock distribution on synchronous performance. The control of any differences and uncertainty in the arrival times of the clock signals can limit the maximum performance of the entire system and create race conditions in which an incorrect data signal may latch within a register.
• the clock distribution network often takes a significant portion of the power consumed by a chip; furthermore, significant power can be wasted in transitions within blocks, when their output is not needed. Power may be saved by clock gating, which involves adding logic gates to the clock distribution tree, so portions of the tree can be turned off when not needed.
• a complex field programmable device is the most versatile non-ASIC, as the generic logic cells can be more sophisticated than ASIC cells, and the interconnect structure can be programmable in the field using software, rather than at a fab using for example photolithographic masks.
• a complex field programmable device can be re-programmed to a different circuit in hours, rather than only being programmable once at a fab like an ASIC.
• a complex field programmable device can be broadly divided into two categories, a Complex Programmable Logic Device (CPLD) and a Field Programmable Gate Array (FPGA).
• CPLD Complex Programmable Logic Device
• FPGA Field Programmable Gate Array
• the logic cell of a CPLD is more complex than an FPGA, and has a D-type flip-flop and a programmable logic device semiconductor such as a PALTM type programmable logic device semiconductor, with configurable product terms.
• the interconnect of a CPLD is more centralized, with fewer concentrated routing lines.
• a FPGA logic cell is smaller, with a D-type flip-flop and a small Look Up Table (LUT), a multi input and single output block that is widely used for logic mapping, or multiplexers for routing signals through the interconnect and logic cells.
• LUT Look Up Table
• the interconnect structure in an FPGA tends to be more distributed and flexible than a CPLD, making it more ideal for more high capacity, complex devices.
• the FPGA design that defines a circuit is stored in RAM, so when the FPGA is powered off, the design for the circuit disappears. When the FPGA is powered back up, one must reload the circuit design from non-volatile memory.
• a simple PLD historically called a programmable logic device, is much more limited in application, as they do not have a general interconnect structure.
• Today these devices are relatively rare by themselves and are now used as internal components in an ASIC or CPLD.
• off-the-shelf small and medium scale IC components SSI/MSI
• SSI/MSI small and medium scale IC components
• TTL transistor-transistor logic
• a complex field programmable device can be thought of as a form of programmable logic fabric.
• One such programmable logic fabric is a SRAM programmable Look-Up Table (LUT) technology that forms the basis of Field Programmable Gate Arrays and Complex Programmable Logic Devices.
• the programmable fabric technology allows synthesis of a logic design described in a Hardware Description Language (HDL) to be synthesized on to the logic fabric in order to perform the required logic function.
• the logic fabric includes memory blocks, embedded multipliers, registers and Look-Up Table logic blocks. Interconnect between logic elements is also SRAM programmable. As the state of the SRAM is deleted when powered off, the function of the programmable logic fabric incorporating SRAM can be changed.
• ASIC design flow as a whole is a complex endeavor that involves many tasks, as described further herein, such as: logic synthesis, Design-for-Test (DFT) insertion, Electric Rules Check (ERC) on gate-level netlist, floorplan, die size, I/O structure, design partition, macro placement, power distribution structure, clocks distribution structure, preliminary check, (e.g., IR drop voltage drop, Electrostatic Discharge (ESD)), placement and routing, parasitic extraction and reduction (parasitic devices), Standard Delay Format (SDF) timing data generated by EDA tools, various checks including but not limited to: static timing analysis, cross-talk analysis, IR drop analysis, and electron migration analysis.
• DFT Design-for-Test
• ERC Electric Rules Check
• preliminary check e.g., IR drop voltage drop, Electrostatic Discharge (ESD)
• ESD Electrostatic Discharge
• SDF Standard Delay Format
• the design entry step the circuit is described, as in a design specification of what the circuit is to accomplish, including functionality goals, performance constraints such as power and speed, technology constraints like physical dimensions, and fabrication technology and design techniques specific to a given IC foundry.
• a behavioral description that describes at a high-level the intended functional behavior of the circuit (such as to add two numbers for an adder), without reference to hardware.
• RTL Registered Transfer Language
• RTL focuses on the flow of signals between registers, with all registers updated in a synchronous circuit at the same time in a given clock cycle, which further necessitates in the design flow that the clocks be synchronized and the circuits achieve timing constraints and timing closure.
• RTL description captures the change in design at each clock cycle. All the registers are updated at the same time in a clock cycle for a synchronous circuit.
• a synchronous circuit consists of two kinds of elements: registers and combinational logic. Registers have a clock, input data, output data and an enable signal port. Every clock cycle the input data is stored internally and the output data is updated to match the internal data. Registers, often implemented as flip-flops, synchronize the circuit's operation to the edges of the circuit clock signal, and have memory.
• Combinational logic performs all the logical functions in the circuit and it typically consists of logic gates.
• RTL is expressed usually in a Verilog or VHDL Hardware Description Language (HDL), which are industry standard language descriptions.
• HDL Hardware Description Language
• a hardware description language (HDL) is a language used to describe a digital system, for example, a network switch, a memory or a flip-flop. By using a HDL one can describe any digital hardware.
• a design flow progresses from logical design steps to more physical design steps. Throughout this flow timing is of critical importance and must be constantly reassessed so that timing closure is realized throughout the circuit, since timing between circuits could change at different stages of the flow. Furthermore, the circuit must be designed to be tested for faults. The insertion of test circuitry can be done at the logic synthesis step, where register transfer level (RTL), is turned into a design implementation in terms of logic gates such as a NAND gate.
• RTL register transfer level
• logic synthesis is the process of generating a structural view from the RTL design output using an optimal number of primitive gate level components (NOT, NAND, NOR, and the like) that are not tied to a particular device technology (such as 32 nm features), nor do with any information on the components' propagation delay or size.
• NOT primitive gate level components
• NOR NOR
• the circuit can be manipulated with Boolean algebra.
• Logical synthesis may be divided into two-level synthesis and multilevel synthesis. Because of the large number of fan-ins for the gates (the number of inputs to a gate), two-level synthesis employs special ASIC structures known as Programmable-Logic Arrays (PLA) and modified Programmable Array Logic (PAL)-based CPLD devices.
• PLA Programmable-Logic Arrays
• PAL Programmable Array Logic
• Multilevel synthesis is more efficient and flexible, as it eliminates the stringent requirements for the number of gates and fan-ins in a design, and is preferred.
• the multilevel synthesis implementation is realized by optimizing area and delay in a circuit.
• optimizing multilevel synthesis logic is more difficult than optimizing two-level synthesis logic, and often employs heuristic techniques.
• Functional synthesis is performed at the design entry stage to check that a design implements the specified architecture. Once Functional Verification is completed, the RTL is converted into an optimized gate level netlist, using smaller building blocks, in a step called Logic Synthesis or RTL synthesis. In EDA this task is performed by third party tools.
• the synthesis tool takes an RTL hardware description and a standard cell library for a particular manufacturer as input and produces a gate-level netlist as output.
• the standard cell library is the basic building block repository for today's IC design. Constraints for timing, area, speed, testability, and power are considered. Synthesis tools attempt to meet constraints by calculating the engineering cost of various implementations.
• the tool attempts to generate the best gate level implementation for a given set of constraints, target the particular manufacturing process under consideration.
• the resulting gate-level netlist is a completely structural description with only standard cells at the "leaves" of the design.
• the netlist is typically modified to ensure any large net in the netlist has cells of proper drive strength (fan out), which indicates how many devices a gate can drive.
• a driving gate can be any cell in the standard cell library.
• the EDA tool many adjust the size of the gate driving each net in the netlist so that area and power is not wasted in the circuit by having too large of a drive strength. Buffer cells are inserted when a large net is broken info smaller sections by the EDA tool.
• an EDA tool performs a computer simulation of the layout before actual physical design.
• the next step in the ASIC flow is the physical implementation of the gate level netlist, or physical design, such as system partitioning, floorplanning, placement and routing.
• the gate level netlist is converted into a geometric representation of the layout of the design.
• the layout is designed according to the design rules specified in the library for the fab that is to build the digital device.
• the design rules are guidelines based on the limitations of the fabrication process.
• the physical implementation step consists of several sub steps: system partitioning, floorplanning, placement and routing. These steps relating to how the digital device is to be represented by the functional blocks, as one ASIC or several (system partitioning), how the functional blocks are to be laid out on one ASIC (floorplanning) and how the logic cells can be placed within the functional blocks (placement) and how these logic cells are to be interconnected with wiring (routing).
• the file produced at the output of this physical implementation is the so-called GDSII file, which is the file used by the foundry to fabricate the ASIC.
• Floorplanning involves inputting into a floorplanning tool a netlist that describes the interconnection of ASIC blocks (RAM, ROM, ALU, cache controller, and the like); the logic cells (NAND, NOR, D flip-flop, and so on) within the blocks; and the logic cell connectors (e.g., terminals, pins, or ports).
• Floorplanning maps the logical description as found in the netlist to the physical description, the floorplan.
• the goals of floorplanning are to arrange the ASIC blocks on the silicon chip, to decide the location of the I/O pads, to decide the location and number of the power pads, the type of power distribution, and the location and type of clock distribution. Design constraints in floorplanning include minimizing the silicon chip area and minimizing timing delay. Delay is often estimated from the total length of the interconnect and from an estimate of the total capacitance. Interconnect length and predicted interconnect capacitance is estimated from statistics of previously routed chips, including such factors as net fanout and block size of the circuits in the ASIC.
• timing is effected since the length of an interconnect caused by placement changes the capacitance of the interconnect and hence changes the delay in the interconnect.
• the goal of an EDA placement tool is to arrange all the logic cells within the flexible blocks on a chip to achieve objectives such as: guarantee the router can complete the routing step, minimize all the critical net delays, make the chip as dense as possible, minimize power dissipation, and minimize cross talk between signals.
• Modern EDA placement tools use even more specific and achievable criteria than the above.
• the most commonly used placement objectives are one or more of the following: minimize the total estimated interconnect length, meet the timing requirements for critical nets, and minimize the interconnect congestion.
• MRST minimum rectilinear Steiner tree
• the determination of the MRST is in general a NP-complete problem—which is difficult to solve in a reasonable time.
• NP-complete problem For small numbers of terminals heuristic algorithms exist, but they are expensive in engineering cost to compute.
• EDA tools Several approximations to the MRST exist and are used by EDA tools.
• a Structured ASIC cross-section has metal layers; in a standard cell ASIC there may be nine metal layers, but in many structured ASICs not all metal layers need be for routing, and some layers may be pre-routed, and only the top layers are used for routing. This reduces the complexity of the manufacturing process, since non-recurring engineering costs are much lower, as photolithographic masks are required only for the fewer metal layers not for every layer, and production cycles are much shorter, as metallization is a comparatively quick process.
• the metal layers may be interconnected with one another at select vertical holes called vias that are filled with metal or some conductor, called the 'via' layer, and thus be configurable at this interconnecting layer, or 'via configurable'.
• the logic fabric comprising the Structured ASIC is configured with traditional IC optical lithography involving photolithographic masks, it can be thought of as "mask programmable”.
• the mask for a Structured ASIC is programmed at the vias, which can be termed a via- configurable logic block (VCLB) architecture.
• the VCLB configuration and programmability may be performed by changing properties of so called “configurable vias" - connections between VCLB internal nodes.
• a configurable or programmable via may be in one of two possible states: it may be either enabled or disabled. If a programmable via is enabled, then it can conduct a signal (i.e., the via exists and has low resistance).
• the customizable metallization layers may be reduced to a few or even a single via layer where the customization is performed, see by way of example and not limitation U.S. Pat. No. 6,953,956, issued to eASIC Corporation on October 1 1 , 2005; U.S. Pat. No. 6,476,493, issued to eASIC Corporation on November 5, 2002; and U.S. Pat. No. 6,331 ,733, issued to eASIC Corporation on December 18, 2001 ; all incorporated herein by reference in their entirety. Further, this single via layer could be customized without resorting to mask-based optical lithography, but with a maskless e-beam process, as taught by the '956 patent.
• a back-annotated netlist is used with timing information to see if the physical design has achieved the objectives of speed, power and the like specified for the design. If not, the entire ASIC design flow process is repeated.
• the delays calculated from a simulation library of library cells used in the design, during physical design steps, are placed in a special file called the SDF (Synopsys Delay Format) file.
• SDF Synopsys Delay Format
• Each cell can have its own delay based on where in the netlist it is found, what are its neighboring cells, the load on the cell, the fan-in, and the like.
• Each internal path in a cell can have a different propagation time for a signal, known as a timing arc.
• the maximum possible clock rate is determined by the slowest logic path in the circuit, called the critical path.
• Clock skew can be caused by many different things, such as wire-interconnect length, temperature variations and differences in input capacitance on the clock inputs of devices using the clock. Further, timing must satisfy register setup and hold time requirements. Both data propagation delay and clock skew play important parts in these calculations. Problems of clock skew can be solved by reducing short data paths, adding delay in a data path, clock reversing and the like. Thus during the physical synthesis steps, clock synthesis is an important step, which distributes the clock network throughout the ASIC and minimizes the clock skew and delay.
• IP in the form of proprietary third party functionality such as a semiconductor processor may be embedded in an ASIC using soft macros, firm macros and hard macros that can be bought from third parties.
• a soft macro describes the IP as RTL code and does not have timing closure given the design specification nor layout optimization for the process under consideration.
• RTL code a soft macro can be modified by a designer with EDA tools and synthesized into the designer's library.
• a hard macro is timing- guaranteed and layout-optimized for a particular design specification and process technology but is not portable outside the particular design and process under consideration, and is not represented in RTL code; rather a hard macro is tailored for a particular foundry and closer to GDSII layout.
• a firm macro falls between a hard macro and a soft macro.
• Firm macros are in netlist format, are optimized for performance/area/power using a specific fabrication technology, are more flexible and portable than hard macros, and more predictive of performance and area to be used than soft macros. Macros obviate a designer having to design every component from scratch, and are a great time saver. Third party designers favor firm and hard macros since it is easier to hide intellectual property (IP) present in such macros than it is to hide such IP in a soft macro.
• IP intellectual property
• the pros and cons of standard cell ASICs versus a complex field programmable device such as an FPGA is as follows.
• the advantages of FPGAs are that they are easy to design, have shorter development times and thus are faster in time-to-market, and have lower NRE costs.
• the disadvantages of FPGAs are that design size is limited to relatively small production designs, design complexity is limited, performance is limited, power consumption is high, and there is a high cost per unit.
• These FPGA disadvantages are standard-cell advantages, as standard cells support large and complex designs, have high performance, low power consumption and low per-unit cost at a high volume.
• a Structured ASIC falls between an FPGA and a Standard Cell-based ASIC in classification and performance. Structured ASICs are used for mid-volume level designs. In a Structured ASIC the task for the designer is to map the circuit into a fixed arrangement of known cells.
• Structured ASICs are closer to standard-cells in their advantages over FPGAs.
• the disadvantage of structured ASICs compared to FPGAs is that FPGAs do not require any user design information during manufacturing. Therefore, FPGA parts can be manufactured in larger volumes and can exist in larger inventories. This allows the latency of getting parts to customers in the right volumes to be reduced.
• FPGAs can also be modified after their initial configuration, which means that design bugs can be removed without requiring a fabrication cycle. Design improvements can be made in the field, and even done remotely, which removes the requirement of a technician to physically interact with the system.
• structured ASICs combine the best features of FPGAs and standard cell ASICS.
• Structured ASICs can have three main architectures: fine-grained, where the structured elements are unconnected discrete components, including transistors, resistors and other components; medium-grained, where the structured elements contain generic logic, such as gates, MUXs, LUTs or flip-flops; and, finally, hierarchical design, which contains mini-structured elements such as gates, MUXs and LUTs but no flip-flops for storage, with the flip-flops or registers added later.
• Hierarchical design has blocks and sub-blocks in a hierarchy, and takes more run time in an EDA tool than a flat design to build.
• fine-grained structured ASICs require many connections in and out of a structured element, while the higher granularities reduce connections to the structured element but decreases the functionality they can support. Each individual design will benefit differently at these various granularities.
• Structured ASIC advantages over standard cell ASICs and FPGAs include that they are largely prefabricated, with components are that are almost connected in a variety of predefined configurations and ready to be customized into any one of these configurations. Only a few metal layers are needed for fabrication of a Structured ASIC, which dramatically reduces the turnaround time. Structured ASICs are easier and faster to design than standard cell ASICs. Multiple global and local clocks are prefabricated in a Structured ASIC. Consequently, there are no skew problems that need to be addressed by the ASIC designer. Thus signal integrity and timing issues are inherently addressed, making design of a circuit simpler and faster. Capacity, performance, and power consumption in a Structured ASIC is closer to that of a standard cell ASIC. Further, structured ASICs have faster design time, reduced NRE costs, and quicker turnaround than standard cell ASICs. Thus with structured ASICs the per-unit cost is reasonable for several hundreds to 100k unit production runs.
• a technology comparison between standard cell ASICs, structured ASICs, and FPGAs, respectively, is roughly as follows: generally speaking, there is a ratio of 100:33:1 between the number of gates in a given area for standard cell ASICs, structured ASICs, and FPGAs, respectively; a ratio of 100:75:15 for performance (based on clock frequency); and a ratio of 1 :3:12 for power, though these ratios change year by year and at different process lithographic nodes.
• the unit price of a Structured ASIC solution may be reduced by a significant amount due to the removal of the storage and logic required for configuration storage and implementation.
• the unit cost of a Structured ASIC may be somewhat higher than a full custom ASIC, primarily due to the imperfect fit between design requirements and a standardized base layer, with certain I/O, memory and logic capacities.
• Structured ASIC products may be differentiated by the point at which the user customization occurs and how that customization is actually implemented. Most structured ASICs may only standardize transistors and the lowest levels of metal. A large set of metal and via masks may be needed in order to customize a product. This yields a marginal cost reduction for NRE. Manufacturing latency and yield benefits may also be compromised using this approach.
• An ideal ASIC device may combine the field programmability of FPGAs with the power and size efficiency of ASICs or structured ASICs.
• SoC system-on-chip
• the components of a SoC vary with the application. Some SoCs contain mixed signal and analog input/output (IO), but usually most of a SoC is digital.
• the SoC may contain memory, CPUs (central processing units) / microprocessors, busses, specialized logic and other digital functions.
• the architecture of the SoC is tailored to an application rather than being general-purpose.
• a FET Field Effect Transistor
• a common type of FET is the Metal Oxide Semiconductor FET (MOSFET).
• MOSFET work by inducing a conducting channel between two contacts called the source and the drain by applying a voltage on the oxide-insulated gate electrode.
• MOSFET Two types of MOSFET are called nMOSFET (commonly known as nMOS or NFET) and pMOSFET (commonly known as pMOS or PFET) depending on the type of carriers flowing through the channel.
• nMOS transistor is made up of n-type source and drain and a p-type substrate.
• nMOS logic is easy to design and manufacture, but devices made of nMOS logic gates dissipate static power when the circuit is idling, since DC current flows through the logic gate when the output is low.
• a pMOS transistor is made up of p-type source and drain and a n-type substrate. PMOS technology is low cost and has a good noise immunity.
• carriers are electrons, while in a pMOS, carriers are holes; since electrons travel faster than holes, all things being equal NFETs are twice as fast as PFETs.
• nMOS When a high voltage is applied to the gate, with the gate-source voltage exceeding some threshold value ( V G s > V T H ), the nMOS will conduct, while pMOS will not; and conversely when a low voltage is applied in the gate, nMOS will not conduct and pMOS will conduct.
• PFETs are normally closed switches and NFETs are normally open switches. PFETs often occupy more silicon area than NFETs when forming logic blocks. PMOS devices are more immune to noise than nMOS devices.
• nMOS ICs are smaller than pMOS ICs with the same functionality, since the nMOS can provide one-half of the impedance provided by a pMOS under the same geometry and operating conditions.
• CMOS Complementary metal-oxide-semiconductor
• COS-MOS complementary- symmetry metal-oxide-semiconductor
• the words "complementary- symmetry" refer to the fact that the typical digital design style with CMOS uses complementary and symmetrical pairs of p-type and n-type metal oxide semiconductor field effect transistors (MOSFETs) for logic functions.
• MOSFETs metal oxide semiconductor field effect transistors
• Complementary Metal-Oxide-Silicon circuits require an nMOS and pMOS transistor technology on the same substrate. An n-type well is provided in the p-type substrate.
• CMOS circuits contain pMOS devices, which are affected by the lower hole mobility, CMOS circuits are not faster than their all- nMOS counter parts. Even when scaling the size of the pMOS devices so that they provide the same current, the larger pMOS device has a higher capacitance.
• CMOS complementary metal-oxide-semiconductor
• VLSI/ULSI very/ultra large-scale integration
• a multiplexer (MUX or mux), sometimes called a data selector, is a circuit that selects one of several analog or digital input signals and forwards the selected input into a single line.
• a multiplexer of 2n inputs has n select lines, which are used to select which input line to send to the output.
• Demultiplexers take one data input and a number of selection inputs, and they have several outputs.
• a decoder is a circuit that performs the reverse operations of an encoder.
• DCDL Digitally Controlled Delay Line
• Minimum delay occurs from a DCDL circuit design architecture if a clock signal has to pass through a number of delays before it can be output again, with each of these delays summing together to produce a minimum delay that may be unacceptably large for a design.
• Range is a function of how many stages can be safely added to a design to still achieve a scalable, useable output, and depends on the architecture. Clock glitches should always be avoided but are sometimes unavoidable in certain DCDL architectures that are otherwise acceptable.
• Figure 1 shows an example of a "fine tuning'" DCDL delay unit 10, comprising a CMOS configuration having plurality of pMOS transistors and nMOS transistors in parallel that surround an inverter 32 having an input IN and an output OUT through which a clock signal is delayed.
• the DCDL 10 comprises, in the pMOS transistors, a first transistor, 13, having a gate 12, a second transistor ⁇ 1 , 15, in parallel with the first transistor 13, the second transistor ⁇ 1 having a gate 14, and a last transistor, T'21 , 17, having a gate 16, in parallel with the other pMOS transistors, which all except the first transistor have their gates connected to output lines from a 2-bit Binary-to-Thermometer Decoder 20, that controls their gate voltages through a plurality of voltage thresholds output as a control signal by the Binary-to- Thermometer Decoder 20.
• a source Vss comprising a negative supply voltage or ground is connected to the gate 12 of the first transistor 13 while the remaining gates are connected to predetermined outputs 21 from the 2-bit Binary-to-Thermometer Decoder 20, the outputs 21 forming control signals.
• the 2-bit Binary-to-Thermometer Decoder 20 supplies a plurality of different voltages T, output in response to a two-bit binary code signal input as thermometer values (unary coding), meaning for example a binary 0 is output as 000, a binary 1 is output as 001 , a binary 2 is output as 01 1 , a binary 3 is output as 1 1 1 , a binary 4 is output as 1 1 1 1 , a binary 5 is output as 1 1 1 1 1 , a binary 6 is output as 1 1 1 1 1 1 1 , a binary 7 is output as 1 1 1 1 1 1 1 , a binary 8 is 1 1 1 1 1 1 1 1 , a binary 9 is 1 1 1 1 1 1 1 1 , a binary 10 is 1 1 1 1 1 1 1 1 1 .
• the incorporation of zero is also possible in such a unary coding scheme, as are alternative schemes where the compliment of the output is taken.
• the 2-bit Binary-to-Thermometer Decoder 20 will convert a 2-bit binary number input into an equivalent thermometer value output, which can represent voltage values.
• an equivalent thermometer value output which can represent voltage values.
• a predetermined thermometer voltage value output is received by the gates 12, 14, and 16 of pMOS transistors 13, 15, and 17, and the gate-source voltage of the P-type MOSFETs exceeds the threshold value, certain of the pMOS transistors will conduct, depending on the value received. This increases the flow of the current into the source of the PFET transistor 22, which forms part of the inverter 32.
• Increasing the thermometer values output from decoder block 20 from a low number to higher number will cause more of the pMOS transistors at the top of the circuit to conduct.
• thermometer voltage values are input into the nMOS transistors 24, 26 and 28, connected in parallel as shown.
• the first nMOS transistor 24 is connected at its gate to Vdd, the positive supply voltage, and certain transistors, such as nMOS transistors 26, 28, depending on the thermometer voltage value from Decoder block 20 input into their gates, will conduct when their gate-source voltage exceeds a threshold value, which will increase the flow of current into the source of the NFET transistor 30, which forms part of the inverter 32.
• the net effect of increasing the thermometer values is that more current will flow into the sources of the PFET transistor 22 and the NFET transistor 30, which will increase the current flow through inverter 32.
• an aspect of the present invention is to provide a Digitally Controlled Delay Line (DCDL) for a Structured ASIC, manufactured using a CMOS process using NFET/nMOS and PFET/pMOS transistors, which may include together with the DCDL a via-configurable logic block (VCLB) architecture.
• DCDL Digitally Controlled Delay Line
• VCLB via-configurable logic block
• VCLB configuration may be performed by changing properties of so-called "configurable vias" - connections between VCLB internal nodes and elements in a Structured ASIC.
• An aspect of the present invention is to provide a DCDL circuit that combines fine-tuning and coarse-tuning in a single circuit.
• An aspect of the present invention is to provide a DCDL that has a small minimum resolution for delay.
• aspect of the present invention is to provide a DCDL that has a small minimum delay.
• a further aspect of the present invention is for a DCDL that is scalable and has a large range, from minimum delay to maximum delay.
• Another aspect of the present invention is to provide for a DCDL which produces glitch free output over its entire range.
• Yet another aspect of the present invention is to tie the DCDL to a high-speed routing fabric that is automatically balanced, inherently supports a tree, and is scalable.
• orientations such as north-south or east-west are relative to the observer and depend on the chip as outlined in the drawings; hence these orientations are for convenience only and do not limit the invention, other than indicating that the north-south direction is orthogonal to the east-west direction, in the same way that a vertical direction is orthogonal to a horizontal direction.
• FIGURE 1 (Prior Art) is prior art of a fine-tune Digitally Controlled Delay Line (DCDL) circuit.
• DCDL Digitally Controlled Delay Line
• FIGURE 2A is portion of the Digitally Controlled Delay Line (DCDL) circuit of the present invention showing the fine-tune stage.
• DCDL Digitally Controlled Delay Line
• FIGURE 2B is a portion of the Digitally Controlled Delay Line (DCDL) circuit of the present invention showing the coarse-tune stage.
• DCDL Digitally Controlled Delay Line
• FIGURE 3A is a detailed view of the fine-tune portion circuitry of the DCDL
• FIGURE 3B is a detailed view of another embodiment of the fine-tune portion circuitry of the DCDL
• FIGURE 4 shows a plurality of fine-tune and coarse-tune stages comprising the DCDL.
• FIGURE 5 is the floor plan for layout of the Delay Tap, comprising fine-tune delay stage, a coarse-tune delay, and decoders for both.
• FIGURES 6 and 7 are a schematic of the generalized floor plan layout of
• FIGURE 8 shows an IO routing fabric for the Structured ASIC of the present invention.
• FIGURE 9A shows the network-aware IO fabric in which the DCDL appears in, adjacent to a logic unit block used for the Structured ASIC of the present invention.
• FIGURE 9B shows a more detailed close up view of a portion of Fig. 9A.
• FIGURE 10 shows a close up portion of a unit of high-speed routing fabric of the kind employed with the DCDL of the present invention.
• FIGURE 1 1 shows the high-speed routing fabric as it is deployed in the
• Structured ASIC of the present invention for use with the DCDL.
• the method and apparatus of the present invention may be described in software, such as the representation of the invention in an EDA tool, or realized in hardwire, such as the actual physical instantiation.
• the Digitally Controlled Delay Line (DCDL) of the present invention is for delaying input or output signals, such as PLL, DLL or clock signals, but may also include delaying IO signals (which sometimes require delay due to various IO standards) and other signals into or out of the core logic 715 of the chip 100, which is shown in the drawings in Figs. 6 and 7, termed the Ruby architecture.
• the DCDL also can be used with any Phase Locked Loops (PLLs) or DLL in the peripheral IO regions of the core of the RUBY chip such as IO region 630, as shown in Fig. 8.
• PLLs Phase Locked Loops
• Each delay line may be composed of eight independent Delay Taps, as further described herein and as shown in Fig. 9A, that can be connected in series to achieve the biggest delay, each delay line made into a macro 910 that is to fit in the space 620 between the IO routing fabric 630 and the core 715, and each delay line fits next to a logic block eMotif 603.
• the delay line blocks may be placed into an IO fabric 660 deemed elOMOTIF, as shown in Figs. 6, 7 and 9A, which fits in space 620.
• the DCDL can be treated as a sub macro of the elOMOTIF fabric and operatively connected thereto.
• the controller for the DCDL is found in the core 715, and has its own control logic.
• the lines from the DCDL controller in core 715 to the DCDL that is found in the elOMOTIF portion 660 of the chip are sent in Grey encoded binary code rather than thermometer binary code in order to save space on the chip 100, since Grey code takes fewer signal lines to send and is converted to thermometer code for controlling the DCDL circuit.
• the DCDL delay circuit is implemented using a fine controllable delay section, such as shown in Fig. 2A, and a coarse controllable delay section, such as found in Fig. 2B, in the configuration shown in Fig. 4.
• a multi-stage MUX based lattice is used, such as found in Fig. 4, where the first two stages are implemented for fine grain control, fine delay tuning, followed by multiple stages (e.g. five in Fig. 4) for coarse grain control, coarse grain tuning. All stages have thermometer-based decoding from Gray codes as control signals.
• the first two stages require seven thermometer steps each, that should be decoded from four Gray coded bits, while the coarse stages require one thermometer step per stage (in N stages), and a corresponding number of Gray coded bits (log2N bits compared to the N bits of the thermometer stage).
• Each stage of the lattice primarily consists of a pass-gate mux and an inverter, with suitable control circuitry.
• Figs. 2A, 2B and 4 there is shown the Digitally Controlled Delay Line (DCDL) of the present invention that is used to manipulate a signal, typically a clock signal, by delaying it, and generally has two stages, a fine delay, fine-tune stage 10, determined by a series of transistors in a unique configuration ("sub-gate delay"), and a coarse delay, coarse tune stage 20 determined by a plurality of logical gates (“gate-delay").
• the fine delay and course delay are combined into a plurality of modules in series as best shown in Fig. 4. These modules can be deemed either fine- delay modules (modules 12, 14 in Fig. 4), or coarse-delay modules (modules 22, 24, 26, 28 and 30 in Fig.
• fine delay and course delay being that the resolution in time delay of a signal in a fine-delay module is such that the fine- delay module is capable of delaying a signal by a minimum amount of time less than the amount of time that the signal can be delayed by a course-delay module (e.g., 25 ps for the former versus 100 ps for the latter), or, conversely, a coarse-delay module is capable of delaying a signal by a minimum amount of time that is greater in time than the minimum amount of time that a fine-delay module is capable of delaying the signal, hence the designations of 'coarse' and 'fine', which can also be termed "coarse grain control" and "fine grain control".
• the delay is produced by a delay-producing inverter, which is the simplest form of logic gate to manufacture, but in general this term can designate without loss of generality any logic gate that produces delay.
• the degree of delay that can be produced by the inverter is adjustable, as explained more fully herein.
• the DCDL of Fig. 4 has an initial input A for a signal and final output Z for that signal after it is delayed by the DCDL, and there are two fine-delay, fine grain control, fine-tune or sub-gate delay modules, modules 12, 14 in Fig. 4, connected in series, each having an input A1 and an output Z1 , the output Z1 connected to a neighboring downstream module with output A1 , comprising either another fine-tune module or a coarse-tune module, and the return path comprising an input A2 receiving from an output Z2, with the return path (upstream path) leading to the final output Z of the DCDL 10.
• modules 12, 14 in Fig. 4 connected in series, each having an input A1 and an output Z1 , the output Z1 connected to a neighboring downstream module with output A1 , comprising either another fine-tune module or a coarse-tune module, and the return path comprising an input A2 receiving from an output Z2, with the return path (upstream path) leading to the final output Z of the DCDL 10.
• fine-delay (or fine grain control) modules 12, 14 are followed downstream of the signal path by five course delay, coarse tune, or coarse grain control modules 22, 24, 26, 28, 30 having inputs A1 and outputs Z1 for the downstream path and outputs Z2 inputting into inputs A2 for the upstream return path back to final output Z.
• coarse-delay modules or coarse grain control modules may be used, limited only by the number of thermometer signal lines there are present.
• a total of 2 16 bits may be used to control the fine and coarse stages of the DCDL, and if seven bits are used to control the fine stages, then two fine-stage modules may be employed (7 + 7 ⁇ 16), and if 1 bit is used to control the coarse stages, then up to 16 coarse stages may be employed (though in Fig. 4 only five coarse stages are shown).
• the description of the operation of the five coarse delay modules 22, 24, 26, 28, 30 is that they operate as traditional gate-delay devices comprising muxes, in that when a predetermined control signal is received by the multiplexer, the input signal (typically a clock signal) is either sent to output Z1 or output Z2.
• CMOS transistor configurations 202, 204 act as a pass-gate mux to allow, if instructed by the control line CNTRL, a signal from input A1 , that originated from initial input A that is being passing downstream, to pass through inverter 210 and to continue to output Z1 , downstream, and at the same time a signal from input A2 is allowed to pass through inverter 212, upstream, or, if the proper predetermined control signal is input to control line CNTRL, the signal at input A1 is diverted so the signal passes through inverter 212 and to output Z2.
• DCDL Digitally Controlled Delay Line
• a signal entering into input A2 simply will pass through the pass-gate transistors 204, which may slightly delay the signal, and inverter 212 which further delays the signal, when a predetermined control signal is given at line CNTRL.
• the control signal CNTRL is a thermometer coding control signal.
• a signal received from A2 will pass through to Z2, through the inverter 212 (as well as some small delay caused by pass-gate intermediate transistors) and be delayed by a gate-level delay unit for a certain predetermined time.
• the thermometer-coded control signal at CNTRL instructs the pass-gate mux structure to operate to divert the signal from A1 to Z2, through inverter 212, then the signal will not be further delayed by another neighboring coarse gain module by being sent downstream, but will only be delayed by the coarse gain module primarily by inverters 210, 212 (as well as any small delay from intermediate transistors).
• thermometer-coded control signal at CNTRL instructs the pass-gate mux structure to operate to divert the signal from A1 to Z1
• the signal will be delayed only by inverter 210 while going downstream to the neighboring module, where the signal may be further delayed by the neighboring module.
• the signal passing from A1 to Z1 will then travel to the next downstream neighboring coarse delay module after being output at Z1 , and the downstream neighboring coarse delay module would then have the option of repeating this process of either diverting the input clock signal to any neighboring module at output Z1 after a delay at its inverter 210, or, sending the clock signal through its inverter output Z2, such as inverter 212.
• any return signal to the upstream side will pass through coarse delay module inputs A2 and be delayed primarily by inverter 212, inter alia, and eventually return to final output Z.
• a signal will be delayed by each coarse delay module in Fig. 2B by a predetermined gate-delay unit of time, which is comparatively larger in time than any sub-gate delay, as associated with the fine delay module and as discussed further herein.
• thermometer coded signals can be input into the five coarse delay modules 22, 24, 26, 28, 30 to divert a signal traveling from initial input to final output Z into either one or more modules, designated by their reference number, such as by way of example the coarse delay module delay paths: A ⁇ 22 ⁇ Z; A ⁇ 22 ⁇ 24 ⁇ 22 Z; A ⁇ 22 ⁇ 24 ⁇ 26 ⁇ 24 ⁇ 22 ⁇ Z; A 22 ⁇ 24 ⁇ 26 ⁇ 28 ⁇ 26 ⁇ 24 ⁇ 22 Z; A ⁇ 22 ⁇ 24 ⁇ 26 ⁇ 28 ⁇ 30 ⁇ 28 ⁇ 26 ⁇ 24 - 22 -> Z .
• a signal will be delayed by each module by a gate-delay unit of time, e.g., time Delta T1 Coarse Grain.
• thermometer control signals are output from a coarse delay decoder 230, as shown in Fig. 5, which receives from a DCDL controller, found in the core 715 (not shown) a signal that is output in 4 bit Grey code and is decoded by the coarse delay decoder to produce 15 bits of thermometer code, 1 bit per coarse module. It takes fewer signal lines to send Grey encoded binary signals rather than thermometer binary signals. Hence this arrangement can support up to 15 coarse modules (1 bit per coarse module).
• a signal from the coarse delay decoder may be sent to cause the coarse delay module to divert an input signal along such a signal path as to create gate-level delay, e.g. a signal in thermometer code such as 0000...0001 (ellipses indicating more zeros); while if two coarse gain modules are desired to be activated to delay a signal, the coarse delay decoder can and out a signal 0000...001 1 ; for three gate-delays from three activated coarse gain modules the signal may be 0000...01 1 1 ; and so forth, up to the maximum number of coarse gain modules, with the understanding any number of thermometer encoding schemes may be employed. As can be seen in the Fig. 4 embodiment two of the coarse delay signal lines, D1 and D2, are reserved to control fine delay modules, as will be explained further herein, while the other signal lines D3, D4, D5, D6 control the coarse delay modules.
• the fine-delay modules 12, 14 have the ability to route a signal to be delayed, such as a clock signal, by a more graduated and precise series of unit times, a series of "sub-gate delay” unit times, which are smaller than the coarse grain module "gate-delay” unit of time in their minimum value (minimum resolution), and, when summed together, may be smaller than the coarse grain module gate-delay unit of time.
• a signal to be delayed such as a clock signal
• a series of "sub-gate delay” unit times which are smaller than the coarse grain module "gate-delay” unit of time in their minimum value (minimum resolution)
• minimum resolution minimum resolution
• the fine delay modules are controlled by the same single-bit CNTRL input as the coarse delay modules, but in addition to that input they also have a number of control inputs for that submodule as shown on Fig. 3A.
• the fine delay modules are controlled by the same single-bit CNTRL input as the coarse delay modules, but in addition to that input they also have a number of control inputs for that submodule as shown on Fig. 3A.
• a signal at the input A1 is diverted by employing a control signal at input "CNTRL", which instructs the transistor configurations 242, 244, acting as a pass mux, to either let pass a signal that is to be delayed, to pass from the input line A1 to output Z1 , and to pass through inverter 248 to output Z1 , in which case the signal is not delayed as much (except for a small delay through inverter 248) but will continue to the next downstream module, or, if the correct input control signal at input line "CNTRL” is given, the signal to be delayed passes from A1 through a sub-gate delay logic array 250, as described in more detail in Fig. 3A, and out through to output Z2.
• CNTRL control signal at input "CNTRL”
• an input A2 can receive any signal from a neighboring module, and passes the signal through the sub-gate delay logic array 250. If a signal is passed to output Z1 , it can be delayed by other blocks downstream that are connected in series to the block, such as another fine delay module or by a coarse delay module. Likewise, a return signal going upstream to the output and received at input A2 of fine-delay module 12 or 14 as shown in Fig. 2A can pass through the sub-gate delay logic array 250 if the proper control signal is input at line CNTRL.
• sub-gate delay logic module 250 has as a default delay almost as small as an inverter, but the degree of delay may be varied greater depending on the signals to certain transistors, for example as shown in the embodiment of Fig. 3A, as explained further herein.
• the sub-gate delay logic array 250 is a fine-delay, sub-gate delay circuit shown in detail in the embodiments of Figs. 3A and 3B, and acts to delay the signal by a variable amount.
• the CMOS transistors in parallel comprise transistors 260, 262, 264, 266, 268, 270, 272, 274 (pMOS) and transistors 259, 261 , 263, 265, 267, 269, 272, 273 (nMOS), with the first two transistors 259, 260 from the plurality of CMOS transistors in parallel being connected at their gates to Vdd and Vss, positive and negative (ground) voltage, respectively, and the remaining seven P-type MOSFET transistors 262, 264, 266, 268, 270, 272, 274 that are in parallel to the first transistor 260 and seven N-type MOSFET transistors 261 , 263, 265, 267, 269, 272, 273 that are in parallel to the first transistor 259 having their gates connected to fine-stage decoder thermometer decoder outputs CN1 , CN2, CN3, CN4, CN5, CN6, CN7 for the PFET transistors and fine-stage decoder thermometer de
• 3A can be deemed, for ease in description, as a structure comprising a delay-producing inverter bracketed by a pair of parallel CMOS transistors, with the gate voltages of the parallel pair of CMOS transistors connected to and controlled by a thermometer output signal, and the output of the pair of parallel CMOS transistors leading to and operatively connected to the inverter; in shorthand, this structure, can be called “delay-producing inverter operatively connected to CMOS transistors controlled by a thermometer output” or, even shorter, a "sub-gate delay logic array”.
• thermometer decoder Operation of this delay inverter controlled by thermometer decoder is as follows. When there is the application of a suitable voltage control signal, which is thermometer coded, at gate inputs CN1 , CN2, CN3, CN4, CN5, CN6, CN7 for the PFET transistors and gate inputs C1 , C2.
• a suitable voltage control signal which is thermometer coded
• the pMOS transistors 262, 264, 266, 268, 270, 272, 274 and nMOS transistors 261 , 263, 265, 267, 269, 272, 273 will conduct maximum current via their drains into sources of CMOS transistors 253, 255, which can be shown empirically and theoretically to produce a minimum delay through the inverter 252.
• thermometer coded control signal is output by a Binary-to-Thermometer Decoder that is called a control signal.
• C3, C4, C5, C6, C7 for the NFET transistors comprising the control signal or voltage reference signal is thermometer (Unary coding) based and applied to both the PFET and NFET transistors.
• thermometer Unary coding
• the fine grain sub-gate delay logic array structure shown in Fig. 3A can delay by a variable amount a signal that is input into IN', passed through inverter 252, and output at OUT, the degree of delay depending on the predetermined value of the thermometer based voltage reference signal, which can be termed a control signal, for the fine-tune grain sub-gate delay logic array of Fig. 3A. If the voltage signal is such that all transistors are instructed to be turned off, e.g.
• the signal "1 1 1 1 1 1 1 “ and "0000000” respectively i.e., to turn off all the transistors one uses the signal “1 1 1 1 1 1 “ for PMOS and "0000000” for NMOS
• Delta TMax some predetermined unit of time Delta TMax
• the next smaller delay from Delta TMax is when one of the seven transistors from the PFET transistors 262, 264, 266, 268, 270, 272, 274 and one of the seven transistors from the NFET transistors 261 , 263, 265, 267, 269, 272, 273 are turned on to conduct current, e.g.
• thermometer value for minimum delay would be 10000, i.e. a delay path of A -> 22 -> Z.
• the thermometer value might be 1 1000, i.e. a delay path of A -> 22 - 24 - 22 -> Z.
• the next larger delay after this step might have a thermometer value of 1 1 100, i.e. a delay path of A -» 22 - ⁇ 24 - ⁇ 26 - ⁇ 24 - ⁇ 22 -»Z.
• the maximum delay would be to traverse all the coarse tuning blocks, and might have a thermometer control voltage value of 1 1 1 1 1 , i.e. a delay path of A -> 22 ->24 ->26 - ⁇ 28 - ⁇ 30 - ⁇ 28 - ⁇ 26 -» 24 - ⁇ 22 -» Z.
• a thermometer value of 00000.
• coarse delay may be produced by the fine grain delay modules 12 and 14 (which can take two bits at D1 , D2 in Fig. 4. for coarse grain control), which can be both turned off if no delay is required, or have one fine delay module turned on while the other is off, or have both turned on.
• the fine delay modules 12, 14 can delay a signal by a smaller time than the maximum coarse delay time for each module. Note due to various ways of representing thermometer values, a slightly different way than the above may be used without loss of generality, such as for example the representation of zero or taking the compliment of the zeros to equal ones and vice versa.
• Fig. 3B shows an alternate embodiment sub-gate delay logic array fine-tune portion circuitry 250B to that of the Fig. 3A embodiment for the fine-tune portion circuitry 250 of the DCDL.
• This embodiment 250B provides nearly the same DCDL minimum delay as the fine-tune portion circuitry 250 of the DCDL of Fig. 3A, but is superior because it obtains even better maximum delay, due to the increased capacitance of the input pin A, therefore the overall DCDL range is increased.
• CMOS transistors consisting of pFET transistor 253A, 253B, 253C, 253D, 253E, 253F and nFET transistor 253B, 255B, 255C, 255D, 255E, 255F are connected in parallel to the output Z.
• CMOS transistors consisting of pFET transistor 253A, 253B, 253C, 253D, 253E, 253F and nFET transistor 253B, 255B, 255C, 255D, 255E, 255F are connected in parallel to the output Z.
• a sub-gate delay logic array comprising a delay-producing inverter having a plurality of parallel pFET and nFET transistors, in contradistinction to the fine delay module of the embodiment of Fig. 3A.
• the controlling CMOS transistors comprise transistors 260A, 262A, 264A, 266A, 268A 270A, 272A, 274A (pMOS) and transistors 259A, 261 A, 263A, 265A, 267A, 269A, 272A, 273A (nMOS), with the first two transistors 259A, 260A from the plurality of CMOS transistors being connected at their gates to Vdd and Vss, positive and negative (ground) voltage, respectively, and the remaining seven P-type MOSFET transistors 262A, 264A, 266A, 268A, 270A, 272A, 274A and seven N-type MOSFET transistors 261 A, 263A, 265A, 267A, 269A, 272A, 273A having their gates connected to fine-stage decoder thermometer decoder outputs CN1 , CN2, CN3, CN4, CN5, CN6, CN7 for the
• pFET transistor 266A has its drain tied to the source of pFET transistor 253B, while nFET transistor 265A has its drain tied to the source of nFET transistor 255B, and so on as shown in the diagram.
• connections between the various transistors 253A, 255A, 253B, 255B, 253C, 255C, 253D, 255D, 253E, 255E, 253F, 255F via connections such as shown as centrally extending line C15 (some lines not marked).
• the net effect of this configuration is that the maximum circuit delay is increased because the input pin A has bigger capacitance, though the minimum circuit delay is nearly the same as in the embodiment of Fig. 3A, due to the increased output drive strength.
• the fine-delay structure described in the preceding paragraph and in reference to Fig. 3B can be deemed, for ease in description, as a structure comprising a delay- producing inverter bracketed by a pair of parallel CMOS transistors, with the gate voltages of the parallel pair of CMOS transistors connected to and controlled by a thermometer output signal, and the output of the pair of parallel CMOS transistors leading to and operatively connected to the inverter; in shorthand, this structure, can be called “delay-producing inverter operatively connected to CMOS transistors controlled by a thermometer output” or a "sub-gate delay logic array” for short.
• the pMOS transistors 262A, 264A, 266A, 268A, 270A, 272A, 274A and nMOS transistors 261 A, 263A, 265A, 267A, 269A, 272A, 273A will all conduct maximum current via their drains into sources of CMOS transistors 253A, 253B, 253C, 253D, 253E, 253F and 255A, 255B, 255C, 255D, 255E, 255F, which can be shown empirically and theoretically to produce a minimum delay through the inverter 252A from input A to output Z.
• thermometer coded control signal is output by a Binary-to-Thermometer Decoder that is called a control signal.
• C3, C4, C5, C6, C7 for the NFET transistors comprising the control signal or voltage reference signal is thermometer (Unary coding) based and applied to both the PFET and NFET transistors.
• thermometer Unary coding
• the Structured ASIC 100 has a plurality of logic unit block modules 603 termed eMotif, that contain within, inter alia, via-programmable core logic cells 105, formed of MOSFET transistors.
• the logic modules 603 can be configured to perform any type of random logic, combinational logic or sequential circuit, and may cooperate with memory cells 610, forming a column interspersed between the columns of logic modules, with the logic modules 603 arranged in rows that cooperate with the memory cells 610 found adjacent to the logic.
• the memory cells and logic cells of the core alternate and repeat in layout in columns along the vertical north-south direction to the core.
• the memory is comprised of BRAM (Block RAM) in 512 kb x 18 bits (with an extra bit for repair).
• the logic cell modules 603 and the memory blocks 610 together comprising the logic and memory core 715 of chip 100.
• the logic and memory alternate in a repeating pattern of vertically extending columns in substantially rectilinear or rectangle shaped core 715 as shown in Figs. 6-7, with the columns aligned along a vertical, north-south axis or direction to the core, and repeating to form a scalable architecture.
• the via-programmable IO area comprising an IO sub-bank 630 extends to the left (west) and right (east) of the chip 100 and can access the core 715 as well as the other IO fabrics in chip 100, as well as communicate with the world outside the chip.
• the area taken up by the total IO area, the memory and the logic each comprise roughly 30% of the total chip 100 area layout.
• BIST Busilt-in Self Test
• circuitry 625 exists in the IO area and may be controlled by a microcontroller or by an external tester.
• the BIST fabric 625 is for test and global connections and in one embodiment is three cells wide.
• the core 715 contains logic blocks 603 within it (logic blocks 603, termed eMotif, are best shown in Fig. 9A).
• the first IO routing fabric 630 that is configurable through vias and connects the core 715 to logical pin IO and IO repeater areas for communication with the outside world.
• the first IO routing fabric has a plurality of lOs comprising IO sub-bank 630 comprised of a plurality of lOs termed elOs, each extending horizontally but collectively running on the left and right sides (north/south or vertical) of the core 715.
• IO fabric 660 termed elOMOTIF (best shown in Fig. 9), which lies in the space 620 between the first IO routing fabric 630 and the core 715.
• this IO fabric 660 can be deemed part of the core 715 and is for communication between the logic in the core 715 and IO blocks 670.
• the first IO routing fabric 630 is slower than a second, high-speed IO routing fabric (not shown) having a faster data transfer rate for communication with high-speed IO such as high-speed SerDes (a serial izer/deserializer integrated circuit transceiver that converts parallel data to serial data and vice-versa) and Multi-Gigabit IO (MGIO) block(s) 640, labeled "MGIO".
• This second routing fabric (not shown in the figures) extends east-west at the top of the chip, between the core 715 and the MGIO blocks 640, to facilitate communication with the core 715 and the MGIO blocks 640, and may be operatively tied to the DCDL of the present invention.
• a third IO, third routing fabric (not shown is for communication with a microcontroller in the corner macro 650 and for testing of memory and logic in the core 715.
• a fourth IO routing (best shown in Figs. 10 and 1 1 ), forming a second high-speed routing fabric, lies adjacent the first IO routing fabric, and in a north-south direction, for communication with the first IO routing fabric, and core 715.
• All of these first second, third and fourth routing fabrics are distinct, and ordinarily the first and third routing fabrics dealing with IO and testing are not directly connected, but a designer may decide to operatively connected to one fabric to another and the core 715.
• the first IO fabric of IO sub-bank 630 has four sub-banks 632, 634, 636, 638 on the left side of the Structured ASIC in Fig. 3A and five sub-banks 631 , 633, 635, 637, 639 on the right side.
• DCDL Digitally Controlled Delay Line
• a corner macro 650 that contains a microcontroller or microprocessor block 652 for the Structured ASIC that acts to control, inter alia, JTAG (boundary scan test) logic that is part of the third routing fabric for the core 715.
• the 32 bit microcontroller block 652 is used for a plurality of functions including but not limited to testing of memory and logic, including BIST (Built-in Self Test) testing, and fuse/anti-fuse support for any logic that supports this functionality, such as eFuse block 654, addressing memory, such as memory blocks / cells 610, and initialization and configuration of the chip 100.
• the microcontroller block 652 may also, on-the-fly, configure IP in core 715, through the fabric in the core 715 and/or through JTAG (e.g., IEEE 1 149.1 Standard Test Access Port and Boundary-Scan Architecture) ports.
• the microcontroller 652 can set up test paths inside the chip for BIST and/or scan-chain testing for testing memory and/or logic in core 715, in conjunction with test circuitry and pathways including the network-aware IO fabric (not shown but primarily having network aware logic primarily lying on the top and bottom of the core 715).
• the microcontroller can also set impedance dynamically and digitally in the SerDes of the present invention, as well as any dynamically configurable IO components, through access to a delay tap and perform other such customization of the Structured ASIC through access to the routing fabric.
• the Structured ASIC chip 100 of the present invention has eight signal metal layer (M1 -M8, with one of those eight layers being customizable or via configurable by the customer of the Structured ASIC and the others being fixed prior to customization by the customer), and three metal layers M9/M10/M1 1 for power distribution.
• IO sub-bank blocks generally block 630 (IO routing fabric 630)
• elO individual IO blocks 670 termed elO, these blocks being via-configurable IO blocks, and the entire collection of these IO comprising, due to package restrictions, twenty-eight elO cell blocks in a preferred embodiment, but in general any number may be employed.
• elO cells are via-programmable by a customer employing the Structured ASIC, in order to make the IO accessing the core 715 conform to various standards for accessing the contents of the Structured ASIC.
• two elO cells can make two single-ended lOs or one differential 10.
• the elO cells support different I/O standards requirements during user mode, as well as JTAG and TEST mode.
• Some of the interface standards supported by via-programmable elO cells include, but are not limited to the following interface standards, in various voltages as required by the standards: LVCMOS, PCI, PCI-X, SSTL-2 class 1 , SSTL-2 class 2, SSTL-5 class 1 , SSTL-5 class 2, SSTL-8 class 1 , SSTL-8 class 2, SSTL-12 class 1 , SSTL-12 class 2, SSTL-15 class 1 , SSTL-15 class 2, SSTL-18 class 1 , SSTL-18 class 2, SSTL-35 class 1 , SSTL-35 class 2, HSTL12 class I, HSTL12 class II, HSTL15 class I, HSTL15 class II, HSTL18 class I, HSTL18 class II, ONFI 1 .8V DDR
• IO path areas for power related macros and sub-bank routing include areas for power related macros and subbank routing, and to logical pin IO repeater areas, where any IO signal may be buffered and/or repeated or transmitted for eventual transmission to the logical physical pins that contact the Structured ASIC chip 100 at the periphery, for input/output to external signals.
• the elOMOTIF boundary region 660 can contain logic to configure the elO cell blocks 670, and is also tied to the DCDL blocks, and the elOMOTIF boundary region 660 can be considered part of the core 715.
• IO sub-bank routing blocks 630 For the Structured ASIC chip 100 there are several IO sub-bank routing blocks 630, as can be seen in Fig. 8, with a plurality on one side and the other side of core 715, which contain within them PLLs and DLLs, as need be, as indicated in Fig. 8 as "PPL", and "DLL".
• PLLs have eight-phase rotators 663. Each PLL can produce multiple clock signals and up to eight-phases per clock signal; the eight-phase rotators 663 are muxes that select one of these eight phases with a minimum of glitches, useful for high-speed SerDes.
• EDT (Engineering Design Test) areas 671 and marked as "EDT17" are test logic pins for use by a third party provider, Mentor Graphics, for testing of the chip using scan-chains, as is known per se.
• IO path areas for power related macros and sub-bank routing include the area labeled as "Area for power related macros and subbank routing" in Fig. 8, and then to the logical pin 10 repeater areas 674, where any 10 signal may be buffered and/or repeated or transmitted for eventual transmission to the logical physical pins that contact the Structured ASIC chip 100 at the periphery, for input/output to external signals.
• the DCDL of the present invention is placed in the elOMOTIF IO fabric 660 along the north-south periphery of core 715. Roughly half of the fabric 660 is comprised of DCDL blocks 910, aligned with the rows formed of eMotif logic modules 603, with eight blocks of DCDL blocks 910 for each eMotif logic module 603, as shown in Fig. 9A. In preferred embodiments there may be over 84k to 1 .7M eMotif logic modules 603 in chip 100.
• DCDL blocks 910 were chosen in a preferred embodiment to give the user of the Structured ASIC 100 maximum flexibility in things like adjusting the global clock signal, PLL/DLLs and IO signals, with IO such as found in routing fabric elOMOTIF 660.
• IO such as found in routing fabric elOMOTIF 660.
• FIGs. 7, 9A there is the IO fabric 660 in which the DCDL appears embedded in as DCDL blocks 910, that in a preferred embodiment has eight DCDL modules 910 appear along-side of each eMotif logic module 603, and cooperating with an eMotif logic unit block 603 used for supporting random logic in the Structured ASIC of the present invention.
• full adders 904 surround each four-by-four block 906 of tiled pattern logic block cells 105, that, together with the clock macro 615' and associated flip flops 91 1 , form a cross-shape, and comprise the eMotif eCELL Matrix 603.
• Full adders are often used in addition and complex multiplication of the kind performed by communications ASICs and in multiplexers.
• the full adders 904 can be embedded inside the cells 105 rather than outside as shown.
• the contents of the cells 105 in eMotif 603 may be any kind of logic such as a CLB, though in general the cells 105 comprise transistor based logic. Furthermore these cells 105 may be made of FET transistors manufactured by a CMOS process in the 28 nm or smaller lithographic node. Conventional D flip-flops 91 1 are present in eMotif 603 and can be used in registers and to hold state information; in general any type flip-flops may be used.
• a clock macro 615' in the center of the eMotif eCELL Matrix 603 has routing buffers 913 for efficiently distributing one or more clock signals received from clock trees throughout the chip, as well as providing a local clock signal for the eMotif eCELL Matrix 203.
• the buffers 913 and D-flip-flops 91 1 form a distinctive cross shape in the eMotif eCELL Matrix 603, centered about the clock macro 615'.
• Suitable connecting traces and fabric (not shown) connect the blocks shown in eMotif module 603.
• D flip-flop blocks also known as data flip-flop blocks, four to six D flip-flops per block, can be provided at D flip-flop blocks 952 (called eDFF) for connection to the core logic, and which are also connected to the routing fabric and clock bus lines 920.
• eDFF D flip-flop blocks 952
• clock bus 920B comprising thirty-two signal wires in a preferred embodiment, provides for global clock tree routing (part of these thirty-two wires from a core clock bus come out of the plane of the paper from another layer or layers, i.e., metal layers, and hence cannot be shown in Fig. 9B in their entirety), to cross at cross bar switch area 915.
• Another eighteen vertically extending shielded wires for the clock are shown at routing fabric and clock bus lines 920, which cooperate with the elOCLOCK clock macro 615.
• the elOCLOCK clock macro 615 has three input pathway lines and one output pathway line comprising a plurality of eighteen lines.
• the three input pathway lines are from the north (top), west (left) and south (bottom) sides, and comprise clock lines from the routing fabric and clock bus lines 920 for both the north and south directions, and fourteen lines from a high-speed fabric having connector HS bus connector 935, that may connect to DLLs / PLLs.
• elOCLOCK clock macro 615 is for routing signals, receiving as input lines from high-speed HS bus Connector 935 (which can connect to a high-speed fabric that services for example PLL/DLLs) from the left, routing fabric and clock bus lines 920 from the top and bottom, and outputs 14 lines to the right.
• Clock macro elOCLOCK macro 615 contains a cross bar internally to aid in routing.
• the lines from a high-speed HS bus connector 935 and the clock macro 615 cross with the thirty-two wires of the global clock, core clock bus tree that come out of the plane of the paper for further routing to the eMotif 603.
• the routing fabric and clock bus lines 920 can be tied to the elOMOTIF 660 and consequently DCDL blocks 910 such as shown conceptually with lines 922, for the DCDL blocks to affect the clock signal.
• a high-speed fabric bus (fourteen wires) 930 which typically communicates with DLLs and PLLs, as well as elO cells as explained herein, is connected to a high-speed bus connector 935 which in turn communicates with the clock lines via cross-bar switch 915 and can further be operatively connected to the routing fabric and clock bus lines 920 and DCDL blocks 910.
• the cross-bar switch 915 has and can interconnect in a matrix switch from the following signal lines: in the east-west direction, fourteen lines that ultimately come from the HS bus connector 935 (these lines are routed past the elOCLOCK clock macro 615 and not through it), the output lines, traveling east, of elOCLOCK clock macro 615, and, running vertically, the thirty-two signal wires of the core clock bus 920 (which enter from points that come out of the plane of the paper from a metal layer and entering the plane of the paper in the figure from a substantially orthogonal direction) to enable any vertical line to be connected to any horizontal line.
• the output of the cross-bar switch 915 extends horizontally into the eMotif logic module 603.
• Fig. 10 is a more detailed schematic close up of another high-speed routing fabric 1080 of the present invention (a fourth routing fabric) used to communicate with high-speed devices.
• this fourth routing fabric high-speed routing fabric 1080 running vertically north-south on chip 100, appears in structure very similar to the second routing fabric at the top of the chip, which runs horizontally (east-west), but the two high-speed fabrics are different in application.
• the high-speed fabric 1080 connects IO logic block 603 and memory cells 610 of core 715 of the Structured ASIC chip 100 with the DCDL, clock, IO region 630 and memory or communication interfaces (e.g.
• DDR SDRAM double data rate synchronous dynamic random-access memory
• the fabric 1080 fits along the north-south extending vertical sides of the substantially rectilinear chip 100.
• high-speed (HS) routing fabric 1080 may communicate through an interface with any high-speed memory such as DDR found outside the chip, the clock network of chip 100, the PLLs/DLLs of the first routing fabric and may exist on any of the metal layers.
• the high-speed third routing fabric 1080 may be connected to the high-speed fabric bus 930 (fourteen wires in Fig. 9B), which typically communicates with DLLs and PLLs in IO sub-banks 630.
• the high-speed routing fabric 1080 is shielded or double shielded and balanced by its nature, as explained further herein, so any delay from one point to any destination of its branch has the same delay, to allow proper signal and clock routing by its very construction.
• the high-speed routing fabric 1080 of Figs. 10, 1 1 can form a type of crossbar switch, accepting multiple inputs and giving multiple outputs, as explained below, and in a preferred embodiment giving a balanced binary tree having at least two nodes at each branch.
• the HS routing fabric is composed of a plurality of units, such as HS units 1082, 1084, with unit 1084 simply being unit 1082 rotated by 180 degrees.
• Each eMotif logic block 603 will have four of such HS units operatively abutting it, servicing it. Extending vertically, there may be hundreds of such HS units, depending on the number of eMotif logic blocks 603 present.
• the HS units have on both the left and right sides vertically extending power and ground lines 1086, 1088, which are somewhat larger in diameter than the vertically extending signal wires or lines remaining, fourteen of which are shown, which convey a signal, such as a clock signal or any other high-speed signal.
• Another plurality of horizontally extending wires or lines 1092 also are for carrying signals, and can be made to electrically connect to any vertically extending signal line 1090 by filling a via, in a via programmable manner, such as via 1093, which can be filled or open, as the designer sees fit, to connect the vertically extending signal line 1090 to the horizontal extending signal line 1092.
• the vertical and horizontally crossing wires in the HS units form a planar network where they intersect.
• a plurality of planar connection blocks or connectors 1094 can be made to connect what is normally an open circuit at each of the lines 1092 in which these connectors are placed inline with the lines 1092.
• the lines 1092 go from an open circuit to a closed circuit state and conduct a signal.
• the via programmable planar connection blocks 1094 are placed in a diagonal line as shown, to provide a better layout.
• Inverters or inverting buffers 1096 are placed along a diagonal line to create a balanced signal, facilitate the signal, and connect to the horizontally placed wires 1092.
• each inverter 1096 from the connectors 1094 are equally spaced so any signal that branches from the connector takes the same amount of time to traverse one branch leading up as a signal does to traverse the other branch leading down.
• the HS units 1082, 1084 have a planar network end 1097 and an open end 1098. To form a planar network, as shown, the two planar network ends of HS units 1082, 1084 are abutted end to end.
• Fig. 1 1 shows the HS units of the high-speed routing fabric 1080 arranged in columns next to a single eMotif logic block 603.
• four HS units are shown arranged in each column, such as a plurality of vertically extending (north-south) columns such as HS columns 1 101 , 1 103, 1 105, 1 107 (with ellipses 1 109 indicating more columns may be present, not shown).
• each eMotif block would abut four such HS units and many hundreds of such eMotif blocks 603 would be present— in one preferred embodiment over 1 .77M such eMotif blocks are present.
• eight such HS columns exist on chip 100.
• the last column, 1 107 may actually lie underneath the elOMotif boundary routing region 660 for connection to the eMotif 603.
• the two middle HS units in each column form the main planar network, such as HS units 1 1 1 1 , 1 1 13.
• Each eMotif block 203 would have in a preferred embodiment eight such HS columns in the horizontal direction and many HS units in the vertical direction.
• the high-speed routing fabric of Figs. 10, 1 1 is ideally suited for clock trees in a balanced manner.
• a signal travels along the horizontal direction and has to be split, as is common in a clock tree, into two equal branches that are balanced. This occurs at any planar connector 1094 or at any via 1093 between the vertical and horizontal lines 1090, 1092.
• a signal may be split into two, to travel in two paths, hence in each column there can form any number of branch nodes of a binary tree. With eight columns, and sufficient connections, a signal may be split into 2 ⁇ 8 power or 256 levels or branches. This is ideal for a clock tree.
• FIG. 1 1 An illustration of the myriad connections that may be possible given the structure of Figs. 10, 1 1 may be given, with the understanding a skilled designer can come up with many more configurations from the teachings herein.
• a signal would come in at a horizontal planar connector line, e.g.
• a center planar connection region 1 120 such as for example the second HS column, HS column 1 123, or an adjacent first HS column from another eMotif cell, where there are now two signals on two lines, that are split into four signals.
• a center planar connection region 1 120 such as for example the second HS column, HS column 1 123, or an adjacent first HS column from another eMotif cell, where there are now two signals on two lines, that are split into four signals.
• the HS fabric 1080 abuts a single eMotif 203 module on one side as shown in Fig. 1 1 , but it can support in fact support three columns of such eMotif modules, which are aligned in rows (the other two eMotif modules to the right of eMotif module 603 in Fig. 1 1 not shown for example, which lie in the same row as the HS fabric 1080).
• the unit of the HS fabric 1080 shown in Fig. 1 1 can support three eMotif cells in the same row, and so on (as the HS fabric 1080 extends in the vertical direction in a columnar form), so the HS fabric 1080 can support three columns of eMotif cells.
• the HS fabric 1080 can be operative connected to the elOMOTIF fabric 660, which is tied to both the eMotif cell modules 603 and the elOs of IO sub-bank 630.
• the HS fabric and the trees that are capable of being built in it can support the global clock tree for chip 100.
• the HS fabric 1080 can also support an interface for memory, such as DDR, (DDR SDRAM) and any associated logic for this interface to DDR (the actual DDR memory itself is found outside the chip 100).
• the HS fabric 1080 also supports elOs and DLLs/PLLs in the IO sub-bank 630, including but not limited to single-ended lOs and differential lOs found therein.
• a byte of DDR interface includes data for eight single-ended lOs, a differential IO for any synchronization strobe, and data for the PLL/DLL.
• This DDR interface is readily implementable from the hardware of the present invention, despite the strict requirements for skew, cross-talk and balancing, by utilizing the elOMOTIF fabric, and eMOTIF modules. Using the hardware one could even construct a hard macro to achieve the functionality of the DDR interface. Using the present invention any interface including but not limited to any serial data streams, serial izers / deserializers, network interfaces, and other data interfaces.
• the floorplan of the Structured ASIC is providing an infrastructure for a customer to use to build some sort of circuit of value to the customer, primarily through programmable vias.
• the number of circuits that can be built, and the various interconnections between the elements of the Structured ASIC, is a large set. Any number of connections may be made as can be appreciated by one of ordinary skill in the art from the teachings herein.
• the architecture of the present invention has been found to not produce clock glitches when control signals are in thermometer coding as taught herein, and have a wide range of operation across various process, voltage and temperature (PVT) variations.
• a designer using the architecture for a DCDL of the present invention can thus make various delays, from fine to coarse, over a wide range.
• the present invention achieves glitch free and scalable range DCDL by combining in a serial, pipeline stage manner a sub-gate delay fine stage structure for DCDL in combination with a coarse state structure, as shown in the figures, as long as thermometer coding is employed for the control code, and the control code does not change during a transition of any data signal such as a clock signal.
• the present invention is substantially glitch-free.
• Placement of the blocks that comprise the DCDL of the present invention are shown in Fig. 5, which is the floor plan for layout of the Delay Tap, comprising the fine-tune delay stage, the coarse-tune delay, and decoders for both. Placement of these DCDL blocks may be embedded in the elOMOTIF fabric 660. Each delay line may be composed of eight independent Delay Taps as per DCDL macros 910, that can be operatively connected in series, as shown in Fig. 9 and incorporated into network- aware IO fabric elOMOTIF 660. In the blocks the fine delay stage block 224 is laid next to the coarse delay stage block 226.
• Fine stage decoder block 228 is a Grey-to- Thermometer decoder, as is known per se, and controls the DCDL of the fine delay stage block 224 (as disclosed herein), while coarse stage decoder block 230 controls the DCDL of the coarse delay stage block 226 with another Grey-to-Thermometer decoder (known per se).
• the decoders 220, 222 shown in Fig.5 are glitch free Grey-to- Thermometer code decoders when used in the present architecture, and it can be shown both theoretically and empirically via simulation that a 4-to-15 Grey-to- Thermometer decoder in the present invention will produce a clock glitch free output.
• Fig.5 are glitch free Grey-to- Thermometer code decoders when used in the present architecture, and it can be shown both theoretically and empirically via simulation that a 4-to-15 Grey-to- Thermometer decoder in the present invention will produce a clock glitch free output.
• each "delay line" next to the eMotif module 603 may be composed of eight independent Delay Taps 910, which correspond to the fine and coarse delay modules as specified herein and their decoders, and as laid out in blocks as shown in Fig. 5.
• the controller for the DCDL is found in the core 715, and has its own control logic, with signal lines from the DCDL controller in core 715 sent to the DCDL found in the elOMOTIF fabric 660 as an encoded Grey code signal to save space on the chip 100, since Grey codes are more compact than thermometer value codes and require fewer signal lines or bandwidth to transmit.
• the eight bits sent by the DCDL controller comprise 4 bits intended for coarse delay stage modules and 4 bits intended for the fine-delay stage modules, and from these four bits the fine delay decoder 224 and coarse delay decoder 225 produce 15 bits of thermometer value instructions for the coarse stage modules 22, 24, 26, 28, 30 and 14 bits for the fine stage modules 12, 14 (7 bits for each of the two fine stage modules 12, 14).
• the number of bits sent may be more or fewer depending on how many coarse and fine stage modules are being employed, and are not limited to the numbers shown herein in a preferred embodiment.
• the floorplan of the Structured ASIC is providing an infrastructure for a customer to use to build some sort of circuit of value to the customer, primarily through programmable vias.
• the number of circuits that can be built, and the various interconnections between the elements of the Structured ASIC, is a large set.
• the present semiconductor circuit comprising a DCDL in a via-configurable Structured ASIC
• it may be manufactured on a 28 nm CMOS process lithographic node or smaller and having feature sizes of this dimension or smaller.
• the method of manufacturing the ASIC may be as the flow was described herein in connection with an ASIC and/or Structured ASIC; and the DCDL would be a block of logic within that ASIC.
• the DCDL as well as the floor plan of the Structured ASIC of the present invention are manufactured using a CMOS semiconductor process using NFET/nMOS and PFET/pMOS transistors, which includes a via- configurable logic block (VCLB) architecture.
• VCLB via- configurable logic block
• VCLB configuration may be performed by changing properties of so called “configurable vias" - connections between VCLB internal nodes.
• the configurable vias that are used to customize the chip at a plurality of metal layers, and preferably between two metal layers with a single via layer, and are changed by the customer that deploys the Structured ASIC.
• the customizable metallization layers may be reduced to a few or even a single via layer where the customization is performed, see by way of example and not limitation the patents to the present assignee to this invention, eASIC Corporation, U.S. Pat. No. 6,953,956, issued to eASIC Corporation on October 1 1 , 2005; U.S. Pat. No.
• the delay elements are inverters, but this term should be thought of as synonymous with any sub-gate element that is capable of delaying a signal; inverters are generally favored because the amount of delay produced is relatively small, hence a more fine resolution of delay is possible by the cumulative addition of such delays, but in general any electronic structure that produces delay can be thought of as functioning as and synonymous with the delay-producing inverter taught herein. Thus the scope of the invention is limited solely by the claims.

Landscapes

• Physics & Mathematics (AREA)
• Nonlinear Science (AREA)
• Design And Manufacture Of Integrated Circuits (AREA)
• Pulse Circuits (AREA)

Applications Claiming Priority (2)

Publications (2)

Family

ID=50474832

Family Applications (1)

Country Status (2)

Families Citing this family (21)

Family Cites Families (4)

• 2012
  • 2012-10-11 US US13/649,584 patent/US20140103985A1/en not_active Abandoned
• 2013
  • 2013-10-10 WO PCT/US2013/064383 patent/WO2014059172A2/en not_active Ceased

Also Published As

Similar Documents

Legal Events