CYONS2100 OvationONS™ II Wired Gaming Laser Navigation System-on-Chip Features ■ Description Programmable blocks ❐ Highly integrated mouse-on-a-chip with programmable PSoC® microcontroller unit (MCU) ❐ 32 KB flash memory ❐ 2 KB static RAM (SRAM) ❐ Internal 24-, 12-, or 6-MHz main oscillator (IMO) ❐ Internal 32-kHz low-speed oscillator (ILO) ❐ 16-bit data report enables simultaneous high-speed and high-resolution tracking ■ Tracking performance ❐ Continuously variable resolution: 400 to 3200 counts per inch (CPI), independent of speed ❐ High speed with high accuracy tracking ❐ Speed up to 75 inches per second (in/s) ❐ Acceleration up to 30 g ■ Peripheral interface ❐ Integrated full-speed USB for wired applications ❐ SPI master for interface to external functions 2 ❐ Fast or standard mode I C ■ 28 general purpose input/output (GPIO) pins ❐ Port 0 - 8 bits ❐ Port 1 - 8 bits with high-current capability, regulated output voltage, and 5 V input tolerance ❐ Port 2 - 8 bits ❐ Port 3 - 4 bits The CYONS2100 is a member of Cypress Semiconductor’s second generation laser navigation System-on-Chip (SoC) family of products. Powered by the high-speed and high-precision OptiCheck™ technology, along with the world-leading PSoC technology, this family integrates the sensor, USB, and MCU functions into one chip. Bundled with the VCSEL into one package, the combination forms the market’s first true mouse-on-a-chip solution. The CYONS2100 is the version that is designed for high performance gaming applications. Enabled by the Cypress 0.13-micron mixed signal process technology, the device integrates the OptiCheck sensor with full-speed USB into a single silicon chip that enables seamless communication between the sensor and MCU/full-speed USB. The sensor provides the best translation of hand motion into true gaming motion on PC. This highly integrated solution is programmable. It provides mouse suppliers the ease-of-use to design a single PCB system and customize their product. With the VCSEL integrated in the same package, designers do not need to calibrate the laser power during the manufacturing process. This greatly increases production throughput and reduces manufacturing costs. The innovative technology of OvationONS™ II provides high precision, high-speed motion tracking, and low power consumption. Designers can select from a family of integration options, ranging from low-power to high-performance, to target different types of wired and wireless design applications. ■ Power ❐ Internal power system enables operation from 5 V USB or 2.7 to 3.6 V external supply ❐ Self-adjusting power saving modes The CYONS2100 solutions have a small form factor. Along with the lens, each package forms a complete and compact laser tracking system. This datasheet describes the detailed technology capabilities of the CYONS2100. ■ On-chip laser ❐ Vertical cavity surface emitting laser (VCSEL) integrated within the sensor package ❐ No calibration or alignment needed ❐ Electrostatic discharge (ESD) immunity: 2000 V human body model (HBM) ❐ Wavelength: 840 to 870 nm ❐ IEC 60825-1 Class 1 safety: built-in eye-safe fault tolerant laser drive circuitry Figure 1. CYONS2100/CYONSLENS2000 (2-Piece System) ■ Snap-on lens ❐ Molded optic: Self-aligning snap-on molded lens ❐ 6 mm distance between the printed circuit board (PCB) and tracking surface Cypress Semiconductor Corporation Document Number: 001-44046 Rev. *G • 198 Champion Court • San Jose, CA 95134-1709 • 408-943-2600 Revised January 3, 2011 [+] Feedback CYONS2100 Contents OvationONS II Family Performance Table....................... 3 OvationONS II Family Applications ................................. 3 OvationONS II Family Functional Description ................ 3 Pin Description .................................................................. 5 Microcontroller System..................................................... 7 Features ...................................................................... 7 PSoC Functional Overview............................................... 8 The PSoC Core ........................................................... 8 The Analog Multiplexer System................................... 8 Additional System Resources ..................................... 8 Getting Started................................................................... 8 Application Notes ........................................................ 8 Development Kits ........................................................ 8 Training ....................................................................... 8 CYPros Consultants .................................................... 8 Solutions Library.......................................................... 8 Technical Support ....................................................... 8 Technical support – including a searchable Knowledge Base articles and technical forums – is also available online. If you cannot find an answer to your question, call our Technical Support hotline at 1-800-541-4736..................................... 8 Development Tools ........................................................... 9 PSoC Designer Software Subsystems........................ 9 Designing with PSoC Designer ...................................... 10 Select User Modules ................................................. 10 Configure User Modules............................................ 10 Organize and Connect .............................................. 10 Generate, Verify, and Debug..................................... 10 Power Supply Connections ............................................ 11 Overview ................................................................... 11 Understanding DVDD................................................ 11 AVDD, VREGA, and VREGD .................................... 11 Using USB Power...................................................... 11 Using External Power................................................ 11 Filtering and Grounding............................................. 11 Wired Mouse Application Example................................ 12 Electrical Specifications ................................................. 13 Absolute Maximum Ratings....................................... 13 Operating Conditions................................................. 13 Power Consumption .................................................. 14 Power Specifications ................................................. 15 DC GPIO Specifications ............................................ 16 DC Analog Mux Bus Specifications........................... 17 Document Number: 001-44046 Rev. *G DC Low-Power Comparator Specifications ............... 17 DC POR and LVD Specifications .............................. 17 DC Programming Specifications ............................... 18 DC Characteristics - USB Interface........................... 18 AC Chip-Level Specifications .................................... 19 AC General Purpose I/O Specifications .................... 19 AC External Clock Specifications .............................. 20 AC Analog Mux Bus Specifications ........................... 20 AC Programming Specifications................................ 20 AC SPI Specifications ............................................... 21 AC Comparator Specifications .................................. 24 AC I2C Specifications................................................ 24 AC USB Specifications.............................................. 25 PCB Land Pads and Keepout Zones ........................ 26 Orientation of Axes.................................................... 27 PCB Mounting Height and Thickness........................ 27 Thermal Impedances ................................................ 28 Solder Reflow Peak Temperature ............................. 28 Laser Safety Considerations .......................................... 29 Laser Output Power .................................................. 29 Laser Output Power Test Procedure......................... 29 Registration Assistance............................................. 29 Development Tool Selection .......................................... 30 Software .................................................................... 30 Mouse Design Kits .................................................... 30 Development Kits ...................................................... 30 Evaluation Tools........................................................ 30 Device Programmers................................................. 31 Third Party Tools ....................................................... 31 Package Diagrams........................................................... 32 Ordering Information....................................................... 33 Ordering Code Definition........................................... 33 Document Conventions .................................................. 34 Acronyms Used ......................................................... 34 Units of Measure ....................................................... 34 Numeric Naming........................................................ 34 Document History Page .................................................. 35 Sales, Solutions, and Legal Information ....................... 35 Worldwide Sales and Design Support....................... 35 Products .................................................................... 35 PSoC Solutions ......................................................... 35 Page 2 of 36 [+] Feedback CYONS2100 OvationONS II Family Performance Table Parameter Variable resolution Maximum speed CYONS2000 CYONS2001 400, 800, 1600 400, 800, 1600 30 30 CYONS2100 CYONS2101 CYONS2110 Unit 400-3200 400-3200 400-3200 CPI 75 75 75 in/s Maximum acceleration 20 20 30 30 30 g Integrated MCU Yes Yes Yes Yes Yes – CapSense® No No No No 26 inputs – Flash 16 16 32 32 32 KB 2 2 2 2 2 KB SRAM Interfaces Battery supply voltage USB supply voltage External supply voltage Zero motion Full-speed USB 4-wire SPI Full-speed USB 4-wire SPI Full-speed USB 4-wire SPI up to 28 GPIOs 4-wire SPI up to 28 GPIOs 4-wire SPI up to 28 GPIOs up to 28 GPIO up to 28 GPIOs – NA 0.8 to 3.6 NA 0.8 to 3.6 0.8 to 3.6 V 4.25 to 5.25 NA 4.25 to 5.25 NA 4.25 to 5.25 V 2.7 to 3.6 2.7 to 3.6 2.7 to 3.6 2.7 to 3.6 2.7 to 3.6 V 1 1 1 1 1 Count OvationONS II Family Applications ■ Wired and wireless laser mice ❐ Gaming, graphic design, desktop, and mobile mice ■ Optical trackballs ■ Battery powered devices ■ Motion sensing applications OvationONS II Family Functional Description The OvationONS II family is a two-piece laser navigation SoC kit containing the integrated IC package and the molded lens. The 2 kV ESD-rated IC package integrates the VCSEL and laser sensor SoC. Depending on the product selected, the SoC includes an MCU, flash, SRAM, two internal oscillators, CapSense system, battery boost regulator, power regulator, and full-speed USB. The molded lens collimates the VCSEL beam and images the light scattered from the tracking surface to the sensor portion of the laser detector. The lens has features for registration to the package and easily snaps on to the PC board. At the heart of the system is the OptiCheck laser navigation engine. It supports all functions required for tracking, including laser power control, resolution control, and self-adjusting power reduction, which reduces power consumption when motion stops. The laser output power is pre-calibrated to meet the eye safety requirements of IEC 60825 Class 1. The navigation engine is accessed and controlled by an integrated PSoC-based MCU. The interface between the two blocks is through a system bus and a collection of navigation engine interrupts. Full details are available in the OvationONS II Laser Navigation System-on-Chip TRM (Technical Reference Manual) or in the PSoC Designer integrated development environment (IDE) software. Document Number: 001-44046 Rev. *G In addition to controlling the navigation engine, the PSoC MCU also serves as the main application processor. Based on Cypress’s M8C architecture, the PSoC supports a rich instruction set, multiple processor speeds, and flexible GPIOs. Its IMO requires no external crystal. On-chip flash and RAM allow entire navigation systems to be implemented with the single SoC. The OvationONS II family supports a wide range of powering options. Internal regulators minimize the need for external circuitry. Depending on the product selected, the device can be powered from a USB 5-V supply, from a single battery, from dual batteries, or from an external supply. The configuration and use of the power blocks are controlled with the integrated PSoC. Wired sensors include an integrated full-speed USB. As with the navigation engine and power system, the USB block is controlled by the integrated PSoC. All sensors support a 4-wire SPI interface. A typical use of the SPI interface is to provide access to a radio for wireless applications. An I2C interface is also included with all devices. The CYONS2110 device also supports CapSense functions, allowing additional features and differentiation in end products. All features of the OvationONS II family are configured using Cypress’s PSoC Designer™ software, allowing fast application development and time to market. The OvationONS II family block diagram is shown on Figure 2 on page 4. It shows a true SoC solution that enables design cycle reductions along with savings on manufacturing, PCB area, and component inventory management. The packaged solution delivers a fully integrated system that demonstrates tracking performance with efficient power consumption. Page 3 of 36 [+] Feedback CYONS2100 Figure 2. Block Diagram Ovation II Power System OptiCheckTM Navigation System Resolution Control DSP Boost Regulator Battery Filter Power Control POWER BUS f VCSEL Laser Control 3.3V Regulator Port 3 Port 2 Port 1 Port 0 1.8V Analog Regulator PSoC Core Regulator PSoC CORE SYSTEM BUS Global Analog Interconnect SRAM Supervisory ROM (SROM) Interrupt Controller Flash Nonvolatile Memory Sleep and Watchdog CPU Core (M8C) 32 kHz Internal Low Speed Oscillator (ILO) 6/12/24 MHz Internal Main Oscillator (IMO) Multiple Clock Sources SYSTEM BUS Full Speed USB Internal Voltage References System Resets POR and LVD SPI Master/ Slave Three 16-Bit Programmable Timers Digital Clocks I2C Slave ADC CapSense System SYSTEM RESOURCES NOTE: Shaded blocks indicate optional functions - Refer to OvationONSTM II Family Performance Table for details Document Number: 001-44046 Rev. *G Page 4 of 36 [+] Feedback CYONS2100 Pin Description This section describes, lists, and illustrates the CYONS2100 device pins and pinout configurations. The CYONS2100 is available in a 42-pin quad flat no-leads (QFN) package. Table 1. CYONS2100 Pin Description Pin Name Digital Analog Description 1 XRES I Active high external reset with internal pull down 2 DVSS Power 3 DNU 4 DVSS Power Power Digital ground 5 DVDD Power Power Digital supply voltage and regulated output (see Power Supply Connections on page 11) 6 VREGD Power Power Digital VREG 7 AVDD Power Power Analog supply voltage 8 VREGA Power Power Analog VREG 9 P2[7] IO I GPIO port 2 pin 7 10 P1[5] IOHR I SPI MISO, I2C_SDA, GPIO port 1 pin 5 11 P1[3] IOHR I SPI CLK, GPIO port 1 pin 3 12 P2[3] IO I GPIO port 2 pin 3 13 P2[5] IO I GPIO port 2 pin 5 14 P1[7] IOHR I SPI SS, I2C_SCL, GPIO port 1 pin 7 15 P1[1] IOHR I SPI MOSI, ISSP CLK[1], I2C_SCL, GPIO port 1 pin 1 16 P3[3] IOHR I HCLK (OCD high speed clock output), GPIO port 3 pin 3 17 P1[0] IO I ISSP DATA[1], I2C_SDA, GPIO port 1 pin 0 18 P3[5] IO I CCLK (OCD CPU clock output), GPIO port 3 pin 5 19 P1[6] IOHR I GPIO port 1 pin 6 20 P1[2] IOHR I GPIO port 1 pin 2 21 P2[2] IO I GPIO port 2 pin 2 22 P3[7] IO I OCDOE (OCD mode direction pin), GPIO port 3 pin 7 23 P3[1] IO I OCDO (OCD odd data output), GPIO port 3 pin 1 Power Digital ground Do not use 24 OCDE OCD OCD 25 AVSS Power Power 26 P2[1] IO I GPIO port 2 pin 1 27 P2[0] IO I GPIO port 2 pin 0 28 P1[4] IOHR I EXT CLK, GPIO port 1 pin 4 29 P2[4] IO I GPIO port 2 pin 4 30 DVSS Power Power 31 P2[6] IO I GPIO port 2 pin 6 32 P0[0] IO I GPIO port 0 pin 0 33 P0[2] IO I GPIO port 0 pin 2 34 P0[4] IO I GPIO port 0 pin 4 35 P0[6] IO I GPIO port 0 pin 6 36 P0[1] IO I GPIO port 0 pin 1 Document Number: 001-44046 Rev. *G OCDE (OCD even data output) Analog ground Digital ground Page 5 of 36 [+] Feedback CYONS2100 Table 1. CYONS2100 Pin Description (continued) Digital Analog 37 Pin P0[3] Name IO I GPIO port 0 pin 3 Description 38 P0[5] IO I GPIO port 0 pin 5 39 P0[7] IO I GPIO port 0 pin 7 40 D- IO USB data 41 D+ IO USB data 42 VDD5V Power Power 5V power CP DVSS Power Power Center pad (CP) must be connected to digital ground Legend: I=Input; O=Output; H=5 mA High Output Drive, R=Regulated Output, OCD=On-Chip Debug 1 2 3 4 5 6 7 8 9 VDD5V D+ DAI, P0[7] AI, P0[5] AI, P0[3] AI, P0[1] AI, P0[6] 38 37 36 35 34 CYONS2100 QFN (Top View) 33 32 31 30 29 28 27 26 25 24 23 AI, P0[4] AI, P0[2] AI, P0[0] AI, P2[6] DVSS AI, P2[4] AI, EXT CLK, P1[4] AI, P2[0] AI, P2[1] AVSS OCDE AI, OCDO, P3[1] AI, SPI MISO, P1[5] AI, SPI CLK, P1[3] AI, P2[3] AI, P2[5] AI, SPI SS, P1[7] AI, SPI MOSI, ISSP CLK, P1[1] AI, HCLK, P3[3] AI, ISSP DATA, P1[0] AI, CCLK, P3[5] AI, P1[6] AI, P1[2] AI, P2[2] AI, OCDOE, P3[7] 10 11 12 13 14 15 16 17 18 19 20 21 22 XRES DVSS DNU DVSS DVDD VREGD AVDD VREGA AI, P2[7] 42 41 40 39 Figure 3. Pin Diagram Note 1. These are the in-system serial programming (ISSP) pins. Unlike other GPIO’s, they are not high-impedance at power-on reset (POR). See the Technical Reference Manual (TRM) at www.cypress.com or in the PSoC Designer development software for more details. Document Number: 001-44046 Rev. *G Page 6 of 36 [+] Feedback CYONS2100 Microcontroller System ■ Precision programmable clocking ❐ Internal ±5.0% 6-,12-, 24-MHz main oscillator ❐ Internal 32-kHz low-speed oscillator ❐ Support for optional external 32 kHz crystal ❐ 0.25% accuracy for USB with no external crystal ■ Programmable pin configurations ❐ 25-mA sink current on all GPIO ❐ Pull-up, high-Z, open drain, or strong drive modes on all GPIOs ❐ Up to 28 analog inputs on GPIO ❐ Configurable inputs on all GPIOs ❐ Selectable, regulated digital I/O on port 1 • 3.3-, 2.5-, or 1.8-V output ❐ 3.0 V, 20 mA total port 1 source current ❐ 5-mA source current mode on ports 0 and 1 ❐ Hot swap capable ■ Versatile analog mux ❐ Common internal analog bus ❐ Simultaneous connection of I/O combinations ❐ High power supply rejection ratio (PSRR) comparator ❐ Low dropout voltage regulator for the analog array ■ Additional system resources ❐ SPI master and SPI slave • Clock speed up to 12 MHz ❐ Three 16-bit timers ❐ Watchdog and sleep timers ❐ Internal voltage reference ❐ Integrated supervisory circuit ❐ Analog to digital converter (ADC) 2 ❐ I C slave Features ■ Powerful Harvard-architecture processor ❐ M8C processor speed up to 24 MHz ❐ Low power at high-speed ❐ Interrupt controller ❐ Operating temperature range: +5 °C to +45 °C ■ Flexible on-chip memory ❐ 32 KB flash program storage 50,000 erase and write cycles ❐ 2 KB SRAM data storage ❐ Partial flash updates ❐ Flexible protection modes ❐ In-system serial programming (ISSP) ■ Full-speed USB (12 Mbps) ❐ Eight unidirectional endpoints ❐ One bidirectional control endpoint ❐ USB 2.0 compliant ❐ Dedicated 512-byte buffer ❐ Internal 3.3-V output regulator ■ Complete development tools ❐ Free development tool (PSoC Designer) ❐ Full featured in-circuit emulator (ICE) and programmer ❐ Full speed emulation ❐ Complex breakpoint structure ❐ 128 K trace memory Document Number: 001-44046 Rev. *G Page 7 of 36 [+] Feedback CYONS2100 PSoC Functional Overview Getting Started Cypress's Programmable System-on-Chip (PSoC) on-chip controllers combine dynamic, configurable analog and digital blocks and an 8-bit MCU on a single chip, replacing multiple discrete components while delivering advanced flexibility and functionality. A PSoC device includes configurable analog and digital blocks, and programmable interconnect. This architecture enables the creation of customized peripheral configurations, to match the requirements of each individual application. Additionally, a fast CPU, flash program memory, SRAM data memory, and configurable I/O are included in a range of convenient pinouts. For in depth information, along with detailed programming details, see the PSoC® Technical Reference Manual. The architecture for this device family, as illustrated in Figure 2 on page 4, contains: the core, the navigation sensor, the power system, and the system resources (including a full-speed USB port). A common, versatile bus enables connection between I/O and the analog system. A GPIO, which provides access to the MCU and analog mux, is also included. The PSoC Core The PSoC core is a powerful engine that supports a rich instruction set. The PSoC core encompasses SRAM for data storage, an interrupt controller, sleep and watchdog timers, an IMO, and an ILO. The CPU core, called the M8C, is a powerful processor with speeds up to 24 MHz. The M8C is a 4 MIPS, 8-bit Harvard-architecture microprocessor. System resources provide additional capability, such as configurable USB and SPI master-slave communication interface, three 16-bit programmable timers, and various system resets supported by the M8C. The Analog Multiplexer System The analog mux bus connects to every GPIO pin. Pins are connected to the bus individually or in any combination. Analog signals may be routed to an internal ADC. Other multiplexer applications include: ■ Chip-wide mux that enables analog input from any I/O pin ■ Crosspoint connection between any I/O pin combinations For up-to-date ordering, packaging, and electrical specification information, see the latest PSoC device datasheets on the web. Application Notes Cypress application notes are an excellent introduction to the wide variety of possible PSoC designs. Development Kits PSoC Development Kits are available online from and through a growing number of regional and global distributors, which include Arrow, Avnet, Digi-Key, Farnell, Future Electronics, and Newark. Training Free PSoC technical training (on demand, webinars, and workshops), which is available online via www.cypress.com, covers a wide variety of topics and skill levels to assist you in your designs. CYPros Consultants Certified PSoC Consultants offer everything from technical assistance to completed PSoC designs. To contact or become a PSoC Consultant go to the CYPros Consultants web site. Solutions Library Visit our growing library of solution focused designs. Here you can find various application designs that include firmware and hardware design files that enable you to complete your designs quickly. Technical Support Technical support – including a searchable Knowledge Base articles and technical forums – is also available online. If you cannot find an answer to your question, call our Technical Support hotline at 1-800-541-4736. Additional System Resources System resources, some previously listed, provide additional capability useful to complete systems. Additional resources include low-voltage detection (LVD) and power-on reset (POR). The following statements describe the merits of each system resource: ■ ■ The SPI master/slave module ❐ Provides communication over three or four wires ❐ Runs at speeds of 46.9 kHz to 3 MHz (lower for a slower system clock). An I2C slave module ■ LVD interrupts can signal the application of falling voltage levels, while the advanced POR circuit eliminates the need for a system supervisor. ■ An internal reference provides an absolute reference for capacitive sensing. Document Number: 001-44046 Rev. *G Page 8 of 36 [+] Feedback CYONS2100 Development Tools PSoC Designer™ is the revolutionary Integrated Design Environment (IDE) that you can use to customize PSoC to meet your specific application requirements. PSoC Designer software accelerates system design and time-to-market. Develop your applications using a library of precharacterized analog and digital peripherals (called User Modules) in a drag-and-drop design environment. Then, customize your design by leveraging the dynamically generated application programming interface (API) libraries of code. Finally, debug and test your designs with the integrated debug environment including in-circuit emulation (ICE) and standard software debug features. PSoC Designer includes: ■ Application Editor GUI for device and User Module configuration and dynamic reconfiguration ■ Extensive User Module catalog ■ Integrated source code editor (C and Assembly) ■ Free C compiler with no size restrictions or time limits ■ Built in debugger ■ Integrated Circuit Emulation (ICE) Built-in Support for Communication Interfaces: 2 ❐ Hardware and software I C slaves and masters ❐ Full-speed USB 2.0 ❐ Up to 4 full-duplex UARTs, SPI master and slave, and Wireless PSoC Designer supports the entire library of PSoC 1 devices and runs on Windows XP, Windows Vista, and Windows 7. ■ PSoC Designer Software Subsystems Design Entry In the chip-level view you choose a base device to work with and then select different onboard analog and digital components called user modules that use the PSoC blocks. Examples of user modules are ADCs, DACs, amplifiers, and filters. You configure the user modules for your chosen application and connect them to each other and to the proper pins. Then you generate your project. This prepopulates your project with APIs and libraries that you can use to program your application. The tool also supports easy development of multiple configurations and dynamic reconfiguration. Dynamic reconfiguration allows for changing configurations at run time. In essence, this allows you to usemore than 100% of PSoC’s resources for a given application. Document Number: 001-44046 Rev. *G Code Generation Tools The code generation tools work seamlessly within the PSoC Designer interface and have been tested with a full range of debugging tools. You can develop your design in C, assembly, or a combination of the two - the choice is yours. Assemblers. The assemblers allow you to merge assembly code seamlessly with C code. Link libraries automatically use absolute addressing or are compiled in relative mode, and linked with other software modules to get absolute addressing. C Language Compilers. C language compilers are available that support the PSoC family of devices. The products allow you to create complete C programs for the PSoC family devices. The optimizing C compilers provide all the features of C tailored to the PSoC architecture. They come complete with embedded libraries providing port and bus operations, standard keypad and display support, and extended math functionality. Debugger PSoC Designer has a debug environment that provides hardware in-circuit emulation (ICE), allowing you to test the program in a physical system while providing an internal view of the PSoC device. Debugger commands allow a designer to read and program and read and write data memory, read and write I/O registers, read and write CPU registers, set and clear breakpoints, and provide program run, halt, and step control. The debugger also allows the designer to create a trace buffer of registers and memory locations of interest. Online Help System The online help system displays online, context-sensitive help. Designed for procedural and quick reference, each functional subsystem has its own context-sensitive help. This system also provides tutorials and links to FAQs and an Online Support Forum to aid the designer. In-Circuit Emulator A low cost, high functionality In-Circuit Emulator (ICE) is available for development support. This hardware has the capability to program single devices. The emulator consists of a base unit that connects to the PC using a USB port. The base unit is universal and operates with all PSoC devices. Emulation pods for each device family are available separately. The emulation pod takes the place of the PSoC device in the target board and performs full speed (24 MHz) operation. Page 9 of 36 [+] Feedback CYONS2100 Designing with PSoC Designer The development process for the PSoC® device differs from that of a traditional fixed function microprocessor. The configurable analog and digital hardware blocks give the PSoC architecture a unique flexibility that pays dividends in managing specification change during development and by lowering inventory costs. These configurable resources, called PSoC Blocks, have the ability to implement a wide variety of user-selectable functions. The PSoC development process is summarized in four steps: 1. Select User Modules. 2. Configure user modules. 3. Organize and connect. 4. Generate, verify, and debug. Select User Modules PSoC Designer provides a library of prebuilt, pretested hardware peripheral components called “user modules.” User modules make selecting and implementing peripheral devices, both analog and digital, simple. Configure User Modules Each user module that you select establishes the basic register settings that implement the selected function. They also provide parameters and properties that allow you to tailor their precise configuration to your particular application. For example, a pulse width modulator (PWM) User Module configures one or more digital PSoC blocks, one for each 8 bits of resolution. The user module parameters permit you to establish the pulse width and duty cycle. Configure the parameters and properties to correspond to your chosen application. Enter values directly or by selecting values from drop-down menus. All the user modules are documented in datasheets that may be viewed directly in PSoC Designer or on the Cypress website. These user module datasheets explain the internal operation of the user module and provide performance specifications. Each datasheet describes the use of each user module parameter, and other information you may need to successfully implement your design. Document Number: 001-44046 Rev. *G Organize and Connect You build signal chains at the chip level by interconnecting user modules to each other and the I/O pins. You perform the selection, configuration, and routing so that you have complete control over all on-chip resources. Generate, Verify, and Debug When you are ready to test the hardware configuration or move on to developing code for the project, you perform the “Generate Configuration Files” step. This causes PSoC Designer to generate source code that automatically configures the device to your specification and provides the software for the system. The generated code provides APIs with high-level functions to control and respond to hardware events at run time and interrupt service routines that you can adapt as needed. A complete code development environment allows you to develop and customize your applications in either C, assembly language, or both. The last step in the development process takes place inside PSoC Designer’s debugger (access by clicking the Connect icon). PSoC Designer downloads the HEX image to the ICE where it runs at full speed. PSoC Designer debugging capabilities rival those of systems costing many times more. In addition to traditional single-step, run-to-breakpoint and watch-variable features, the debug interface provides a large trace buffer and allows you to define complex breakpoint events that include monitoring address and data bus values, memory locations and external signals. Page 10 of 36 [+] Feedback CYONS2100 Power Supply Connections Figure 4. Power Connections CYONS2100 VDD5V 42 4.25 - 5.25 V 3.3V Regulator External 3.3V Supply, 15 mA max 10 nH 10 uF 10 uF DVDD 5 AVDD 7 USB IO Regulator VREGD 6 VREGA 8 1.8V Digital Circuitry 3V Digital Circuitry 2 DVSS DVSS DVSS Analog GND 3V Analog Circuitry AVSS 25 1.8V Analog Circuitry Digital GND 1.8V PSoC Core Regulator 1.8V Analog Regulator 30 Analog GND 4 Digital GND Analog GND Digital GND Digital GND Digital GND Overview Using USB Power The CYONS2100 incorporates a powerful and flexible powering system. It can be powered from one of two sources: a 5-V supply (typically from the USB VBUS line) or an external 3.3-V supply. Additionally, the CYONS2100’s internal regulators can supply current to external devices. This section describes the capabilities and usage of the power system. Refer to Figure 4 for a block diagram of the CYONS2100’s power system. For most USB applications, the device is powered from the USB VBUS signal. In this case, the 5-V VBUS signal should be connected directly to the CYONS2100’s VDD5V pin. Understanding DVDD DVDD is a unique pin because it can serve as either an input or an output. When the device is powered from USB (using the 3.3-V regulator), DVDD acts as an output, providing a 3.3-V voltage that can be used to power AVDD, VREGD, VREGA, and external parts. When the device is powered from an external 3.3-V supply, DVDD acts as an input only. AVDD, VREGA, and VREGD Using External Power The CYONS2100 can also be powered from an external source. In this case, the external 3.3-V source should connect to DVDD, and VDD5V should be left unconnected. Filtering and Grounding For all designs, it is important to provide proper grounding and proper isolation between the analog and digital power supplies. The analog and digital grounds should be isolated, except for a single connection point that is placed very close to the device. On the supply side, an L-C filter should be placed between AVDD and DVDD, as shown in Figure 4. As with DVDD, these signals power the internal circuitry of the device. Unlike DVDD, these are always inputs. They should be connected as shown in Figure 4. Document Number: 001-44046 Rev. *G Page 11 of 36 [+] Feedback S DP DM GND GND_SHIELD AGND 0.1 uF AVCC AGND 0.1 uF DVCC Zero C4 1M 1 nF 0.1 uF VCC_5V Sensor Decoupling Caps 1 2 3 4 5 10 uF + DVCC 10 nH VCC Filter 22 22 + 10 uF AGND + AVCC DMINUS DPLUS 10 uF Z-WHEEL1 Z-WHEEL2 LF_SW RT_SW CTR_SW 27 26 21 12 29 13 31 9 32 36 33 37 34 38 35 39 1 22 18 16 24 23 P2_0 P2_1 P2_2 P2_3 P2_4 P2_5 P2_6 P2_7 P0_0 P0_1 P0_2 P0_3 P0_4 P0_5 P0_6 P0_7 AGND DD+ ISSP DATA, P1_0 SPI_MOSI, ISSP CLK, P1_1 P1_2 SPI_CLK, P1_3 EXT_CLK, P1_4 SPI MISO, P1_5 P1_6 SPI SS, P1_7 BATT_MON BOOST_GND CYONS2100 XRES OCDOE, P3_7 CCLK, P3_5 HCLK, P3_3 OCDE OCDO, P3_1 U2 CP 43 1 2 3 4 5 25 W G R B SHLD 7 AVDD AVSS Vbus D+/SDATA D-/SCLK GND 8 VREGA VCC_5V DVCC DVCC 5 DVDD AVCC 42 VDD5V VCC_5V 6 VREGD DVSS 30 Document Number: 001-44046 Rev. *G 1206 USB Interface 40 41 17 15 20 11 28 10 19 14 4 2 1 2 2 2 3 Z-WHEEL2 COM GND1 GND2 ENCODER QB QA Z WHEEL SW PUSHBUTTON 1 SW PUSHBUTTON Z-WHEEL1 DMINUS DPLUS 2 SW PUSHBUTTON 1 4 5 1 CTR_SW RT_SW LF_SW Mouse Button Switches CYONS2100 Wired Mouse Application Example Figure 5 shows an implementation of a wired mouse. For complete details, refer to the CY4631 - OvationONS™ II Laser Gaming Mouse Reference Design Kit. Figure 5. Wired Mouse Page 12 of 36 [+] Feedback CYONS2100 Electrical Specifications This section presents the DC and AC electrical specifications of the CYONS2100 device. For the most up-to-date electrical specifications, confirm that you have the most recent datasheet by visiting http://www.cypress.com. Absolute Maximum Ratings Min Typ Max Unit Storage temperature[2] Parameter –40 25 65 °C Case temperature Conditions Operating temperature –15 – 55 °C Case temperature Lead solder temperature – – 260 °C 10 seconds Supply voltage, DVDD, AVDD, VREGA, and VREGD relative to DVSS) – – 3.6 V Supply voltage, VDD5V relative to DVSS – – 5.5 V ESD – – 2.0 kV All pins, HBM MIL 883 method 3015 I/O voltage relative to DVSS –0.5 – DVDD + 0.5 V GPIO ports 0, 2, and 3 I/O voltage relative to DVSS – – 5.5 V GPIO port 1 Latch-up current Maximum current into any GPIO pin – – 100 mA –25 – +50 mA Operating Conditions Min Typ Max Unit Operating temperature Parameter 5 – 45 °C Power supply voltage VDD5V DVDD, AVDD, VREGD VREGA 4.35 2.70 1.71 Power supply rise time 100 – – µs – – 25 mV pp 10 kHz to 50 MHz 10 kHz to 50 MHz Supply noise – AVDD (sinusoidal) Supply noise – VDD, DVDD (sinusoidal) – 5.25 3.60 3.60 Conditions V – – 100 mV pp Distance from PCB to tracking surface 5.80 6 6.20 mm See Figure 15 on page 27 PCB thickness 1.54 – 1.79 mm See Figure 15 on page 27 Note 2. High storage temperature reduces flash data retention time specified in Table 7 on page 18. Recommended storage temperature is 25 ± 25 °C. Extended duration above 65 °C can degrade reliability. Document Number: 001-44046 Rev. *G Page 13 of 36 [+] Feedback CYONS2100 Power Consumption Introduction As described Overview on page 11, the CYONS2100 has a highly advanced power system, which can be used to develop very low power applications. This section describes and specifies the power consumption performance of the device. Enabling Low Power Modes In some cases, designers may want to develop “always-on” applications, with no power-saving modes and consequently no wakeup latency in performance. In other applications, conserving power is crucial, and power-saving modes are a firm requirement. The CYONS2100 enables low-power modes to be enabled or disabled in firmware, either through register writes or through the application programming interface in Cypress’s PSoC Designer development software. The remainder of this section applies to applications requiring power saving modes. with four sets of sleep mode settings, enabling four levels of sleep. By controlling the parameters of these four sleep modes, the designer can tailor the solution to make appropriate tradeoffs between power consumption and wakeup latency. The transition between sleep modes is under the control of the CYONS2100’s digital signal processor (DSP); no firmware needs to be written to manage the transition between modes. Each of the four available sleep modes is defined by three parameters. These parameters are defined as registers that can be controlled by firmware, either through direct register writes or by using the NAV User Module in PSoC Designer. ■ Sleep time: This is the amount of time that the device is in its low-power inactive state. ■ Motion threshold: This is the amount of motion that is required to bring the device out of sleep. ■ Sleep mode time: This is the amount of time that the device stays in a particular sleep mode before transitioning to the next lowest sleep mode. Longer sleep times save power but have higher wakeup latency. Operating Modes From a power consumption standpoint, consider these three operating modes: ■ Tracking mode: In this mode, the device is actively tracking on a surface. It is the highest power mode of the device. The current consumption is slightly dependent on speed and surface. The current, however, is independent of resolution. ■ Inactive mode: In this mode, the device is in its lowest power state. In the inactive mode, the device cannot sense motion, but a timer is running. The timer can generate an interrupt that can wake the rest of the device and start tracking motion. ■ Sleep modes: In sleep modes, the device self-transitions between tracking mode and inactive mode. The typical use of sleep modes is when the device is at rest, but might still be moved. In Sleep modes, the CYONS2100 stays in inactive mode for a fixed time, then wakes up and checks for motion. If motion is detected, the device fully wakes up and begins tracking. If no motion is detected, the device can go back to Sleep mode. Power Management Through Sleep Mode Control Figure 6 shows the flowchart for a particular sleep mode, showing how the three parameters affect behavior. Calculating Power for Sleep Mode The power consumption in sleep mode can be found by using a duty cycle calculation. The sleep mode current is determined by the tracking mode current, the inactive current, the time required to check for motion (typically 2.9 ms), and the time between check-for-motion events. The expected current consumption is given by the formula I TRACK × 2.9 + I INACT × T SLEEP I SLEEP = ----------------------------------------------------------------------------------2.9 + T SLEEP where ISLEEP is the sleep current, ITRACK is the tracking current, IINACT is the inactive current, and TSLEEP is the time (in ms) in the low power state. As an example, if the tracking current is 8.5 mA, the inactive current is 7.5 µA and the sleep time is 100 ms, then the expected sleep current is 0.25 mA. Power management for the CYONS2100 consists of setting the parameters that define the sleep modes. The device is equipped Figure 6. Sleep Mode Flowchart Enter from higher sleep mode Go to sleep for N ms Wake up, check for motion Motion > threshold T? Y Go to active tracking mode N Time in mode > M sec? Y Go to deeper sleep mode N Document Number: 001-44046 Rev. *G Page 14 of 36 [+] Feedback CYONS2100 Power Specifications There are two ways to power the CYONS2100 - external powering and USB powering. Table 4 provides the current consumption values for each mode. With external powering, a 3-V supply is connected to DVDD, AVDD, VREGD, and VREGA, and the internal regulator is turned off. In this case, the current consumption during tracking is ITRACK_EXT, and the consumption during sleep is ISLEEP. With USB powering, the 5-V USB supply is connected to VDD5V, and DVDD, AVDD, VREGD, and VREGA are driven by the internal regulator. Tracking current is specified by ITRACK_USB. Sleep current must include the current consumption of the regulator itself, and is specified by the sum of ISLEEP and IREG5V. Sleep current is achieved by activating “Navigation Sleep Modes” in Cypress’s PSoC Designer development environment. Doing so enables the sleep mode progressions described Operating Modes on page 14. If sleep modes are not activated, the device current stays at tracking levels, even when the device is not sensing motion. ISB_EXT is the current in the lowest power mode of the device. In this mode, the CPU is halted and operation can only be restarted with an external reset at the XRES pin. For designs using the CYONS2100, low-power operation is often only needed to support USB Suspend. The reference code for this is available in the CY4631 - OvationONS™ II Laser Gaming Mouse Reference Design Kit. Table 2. Power Specifications Typ Max Units ITRACK_EXT Tracking current into DVDD, 3.0 V, 25 °C, 5 in/s, 24 MHz IMO, 6-MHz CPU clock, AVDD, VREGD, VREGA white surface, nominal tracking height Symbol Description Conditions Min 9 12.5 mA ITRACK_USB Tracking current into VDD5V 5.25 V, 25 °C, 5 inch/second, 24-MHz IMO, 6 MHz CPU clock, white surface, nominal tracking height, DVDD, AVDD, VREGD, and VREGA powered by internal regulator 12.5 16 mA 7 14 µA IINACT Inactive current into DVDD, AVDD, VREGD, VREGA 3.0 V, 25 °C, CPU in sleep state ISLEEP Sleep current into DVDD, AVDD, VREGD, VREGA 3.0 V, 25 °C IREG5V 5V-to-3 V regulator current consumption VDD5V = 5.25 V, regulator active ISB_EXT Shutdown current into DVDD, 3.0 V, 25 °C, 5 V supply not present AVDD, VREGD, VREGA, all blocks off 4 ISB_USB Shutdown current, all blocks 5.25 V, 25 °C, DVDD, AVDD, VREGA, VREGD off, into VDD5V powered by internal 5V-to-3 V regulator in standby mode 80 Document Number: 001-44046 Rev. *G See Calculating Power for Sleep Mode on page 14 for equation 250 µA 11 µA µA Page 15 of 36 [+] Feedback CYONS2100 DC GPIO Specifications GPIOs are arranged into four ports. Ports 0, 1, and 2 have eight GPIO pins and Port 3 has four GPIO pins. Port 1 has an optional low drop out (LDO) regulator that adjusts the port’s output voltage to 1.8, 2.5, or 3.0 V. Additionally, each GPIO pin can be independently set to one of the four drive modes: strong drive, open drain, pullup, or Hi-Z analog. Rise and fall times are specified for 10% and 90% voltage values. The following tables list guaranteed maximum and minimum specifications for the voltage range of 2.7 V to 3.6 V at the DVDD pin, and over the temperature range 5 °C ≤ TA ≤ 45 °C. Typical parameters apply to 3.3 V at 25 °C and are for design guidance only. Table 3. 2.7 V to 3.6 V DC GPIO Specifications Symbol Description Conditions Min Typ Max Units RPU Pull-up resistor Pin configured for pullup mode. 4.0 5.6 8.0 kΩ VOH1 High output voltage Port 2 or 3 Pins IOH < 10 μA, maximum of 10 mA source current in all I/Os. DVDD 0.2 – – V VOH2 High output voltage Port 2 or 3 Pins IOH = 1 mA, maximum of 20 mA source current in all I/Os. DVDD 0.9 – – V VOH3 High output voltage Port 0 or 1 Pins with LDO Regulator Disabled for Port 1 IOH < 10 μA, maximum of 10 mA source current in all I/Os. DVDD 0.2 – – V VOH4 High output voltage Port 0 or 1 Pins with LDO Regulator Disabled for Port 1 IOH = 5 mA, maximum of 20 mA source current in all I/Os. DVDD 0.9 – – V VOH5 High output voltage Port 1 Pins with LDO Regulator Enabled for 3 V Out IOH < 10 μA, DVDD > 3.1 V, maximum of 4 I/Os all sourcing 5 mA. 2.85 3.00 3.30 V VOH6 High output voltage Port 1 Pins with LDO Regulator Enabled for 3 V Out IOH = 5 mA, DVDD > 3.1 V, maximum of 20 mA source current in all I/Os. 2.20 – – V VOH7 High output voltage IOH < 10 μA, DVDD > 2.7 V, maximum Port 1 Pins with LDO Enabled for 2.5V of 20 mA source current in all I/Os. Out 2.35 2.50 2.75 V VOH8 High output voltage IOH = 2 mA, DVDD > 2.7 V, maximum Port 1 Pins with LDO Enabled for 2.5V of 20 mA source current in all I/Os. Out 1.90 – – V VOH9 IOH < 10 μA, DVDD > 2.7 V, maximum High output voltage Port 1 Pins with LDO Enabled for 1.8 V of 20 mA source current in all I/Os. Out 1.60 1.80 2.10 V VOH10 High output voltage IOH = 1 mA, DVDD > 2.7 V, maximum Port 1 Pins with LDO Enabled for 1.8 V of 20 mA source current in all I/Os. Out 1.20 – – V VOL Low output voltage – – 0.75 V 0.80 IOL = 25 mA, DVDD > 3.3 V, maximum of 60 mA sink current on even port pins (for example, P0[2] and P1[4]) and 60 mA sink current on odd port pins (for example, P0[3] and P1[5]). VIL Input low voltage – – VIH Input high voltage 2.00 – VH Input hysteresis voltage IIL Input leakage (absolute value) Gross tested to 1 μA. CPIN Pin capacitance Temp = 25 °C. Document Number: 001-44046 Rev. *G V V – 80 – mV – 0.5 1.0 µA 0.5 1.7 8.0 pF Page 16 of 36 [+] Feedback CYONS2100 DC Analog Mux Bus Specifications The analog mux bus can connect signals from GPIOs to and from internal analog blocks and other GPIOs. Table 4 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 4. DC Analog Mux Bus Specifications Parameter Description Conditions Min Typ Max Unit RSW Switch resistance to common analog bus Pin voltage < 1.8 V – – 800 Ω RGND Resistance of initialization switch to DVSS Pin voltage < 1.8 V – – 800 Ω DC Low-Power Comparator Specifications The device includes two general-purpose comparators, using internal or external signals from the analog mux bus. Table 5 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 5. DC Low Power Comparator Specifications Parameter Description Conditions Min Typ Max Unit 0.0 – 1.8 V LPC supply current – 10 40 μA LPC voltage offset – 2.5 30 mV VLPC Low power comparator (LPC) common mode Maximum voltage limited to DVDD. ILPC VOSLPC DC POR and LVD Specifications The device features two mechanisms for dealing with low power supply voltages. Both POR and LVD events occur when DVDD falls below a threshold. A POR completely resets the device. An LVD generates an interrupt to the MCU, allowing the application developer to better manage power supply drops. The POR threshold is defined by bits 7 (HPOR) and 5:4 (PORLEV) and of the VLT_CR register at address E3h in register bank 1. The LVD threshold is defined by bits 2:0 (VM) of the same register. Refer to the technical reference manual for more details. Table 6 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 6. DC POR and LVD Specifications Parameter Description VPOR0 VPOR1 VPOR2 VPOR3 DVDD value for POR trip PORLEV[1:0] = 00b, HPOR = 0 PORLEV[1:0] = 00b, HPOR = 1 PORLEV[1:0] = 01b, HPOR = 1 PORLEV[1:0] = 10b, HPOR = 1 VLVD0 VLVD1 VLVD2 VLVD3 VLVD4 VLVD5 VLVD6 DVDD value for LVD trip VM[2:0] = 000b VM[2:0] = 001b VM[2:0] = 010b VM[2:0] = 011b VM[2:0] = 100b VM[2:0] = 101b VM[2:0] = 110b Conditions Min Typ Max Unit DVDD must be greater than or equal to 1.71 V during startup, reset from the XRES pin, or reset from watchdog. 1.61 1.66 2.36 2.60 2.82 1.71 2.40 2.65 2.95 V V V V 2.45 2.71 2.92 3.02 3.13 1.90 1.80 2.51 2.78 2.99 3.09 3.20 1.96 1.84 V V V V V V V – 2.40[3] 2.64[4] 2.85[5] 2.95 3.06 1.84 1.75[6] Notes 3. Always greater than 50 mV above VPOR1 voltage for falling supply. 4. Always greater than 50 mV above VPOR2 voltage for falling supply. 5. Always greater than 50 mV above VPOR3 voltage for falling supply. 6. Always greater than 50 mV above VPOR0 voltage for falling supply. Document Number: 001-44046 Rev. *G Page 17 of 36 [+] Feedback CYONS2100 DC Programming Specifications Table 7 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. The CYONS2100 must be properly powered for Flash programming, with DVDD, AVDD, VREGD, and VREGA all held within the specified range. A suitable option for in-circuit programming USB designs is to apply 5 V to the VDD5V pin, and use the internal regulator to drive DVDD, AVDD, VREGD, and VREGA. This enables direct connection to Cypress’s CY3210-Miniprog. For in-circuit programming of externally-powered designs, the designer must include provisions for supplying DVDD, AVDD, VREGD, and VREGA externally. Table 7. DC Programming Specifications Parameter Description Conditions Min Typ Max Unit 2.7 – 3.6 V VIW Supply voltage for flash write operations VIW applied to DVDD, AVDD, VREGD, and VREGA IDDP Supply current during programming or verify – 5 25 mA VILP Input low voltage during programming or See DC GPIO Specifications on verify page 16. – – VIL V VIHP Input high voltage during programming or See DC GPIO Specifications on verify page 16. VIH – – V IILP Input current when applying VILP to ISSP Driving internal pull-down resistor. CLK and ISSP DATA pins during programming or verify – – 0.2 mA IIHP Input current when applying VIHP to ISSP Driving internal pull-down resistor. CLK and ISSP DATA pins during programming or verify – – 1.5 mA VOLP Output low voltage during programming or verify – – DVSS + 0.75 V VOHP Output high voltage during programming DC GPIO Specifications on page 16. or verify For DVDD > 3 V use the value with IOH = 5 mA. VOH – DVDD V FlashENPB Flash write endurance Erase/write cycles by block. 50,000 – – Cycles FlashDR Flash data retention Following maximum flash write cycles at ambient temp of 45 °C. 5 10 – Years DC Characteristics - USB Interface The device includes an integrated Full-Speed USB block. Table 8 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 8. DC USB Characteristics Symbol Description Conditions Min Typ Max Units Rusbi USB D+ pull-up resistance With idle bus 0.900 - 1.575 kΩ Rusba USB D+ pull-up resistance While receiving traffic 1.425 - 3.090 kΩ Vohusb Static Output high 2.8 - 3.6 V Volusb Static Output low - 0.3 V Vdi Differential input sensitivity 0.2 - Vcm Differential input common mode range 0.8 - 2.5 V Vse Single-ended receiver threshold 0.8 Cin Transceiver capacitance Iio High-Z state data line leakage Rps2 PS/2 pull-up resistance Rext External USB series resistor Document Number: 001-44046 Rev. *G On D+ or D- line In series with each USB pin V - 2.0 V - 50 pF -10 - 10 uA 3 5 7 kΩ 21.78 22 22.22 Ω Page 18 of 36 [+] Feedback CYONS2100 AC Chip-Level Specifications The device has two internal oscillators. The IMO controls the clock speeds for the CPU. A programmable frequency divider allows the CPU to run at lower speeds than the IMO. The ILO is a typically active in sleep modes, clocking sleep, and watchdog timers. Other internal timers can be clocked by either the CPU clock or the ILO. Table 9 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 9. AC Chip-Level Specifications Min Typ Max Unit FIMO24 Parameter IMO frequency for 24 MHz setting Description 22.8 24 25.2 MHz FIMO12 IMO frequency for 12 MHz setting 11.4 12 12.6 MHz FIMO6 IMO frequency for 6 MHz setting 5.7 6.0 6.3 MHz 40 50 setting[7] DCIMO IMO output duty cycle at 6 and 12 MHz FCPU CPU frequency[8] FIMO / 256 F32K1 ILO frequency[9] 19 TRAMP Supply ramp time 20 TXRST External reset pulse width at power-up 1 ms TXRST2 External reset pulse width after power-up 10 μs TMOT Motion delay from reset to valid tracking 60 % FIMO MHz 32 50 kHz – – μs data[10] 30 ms AC General Purpose I/O Specifications GPIOs are arranged into four ports. Ports 0, 1, and 2 have eight GPIO pins and Port 3 has four GPIO pins. Port 1 has an optional LDO regulator that adjusts the port’s output voltage to 1.8, 2.5, or 3.0 V. Additionally, each GPIO pin can be independently set to one of four drive modes: strong drive, open drain, pullup, or Hi-Z analog. Rise and fall times are specified for 10% and 90% voltage values. Specifications are for the entire operating temperature range. Table 10. AC GPIO Specs Parameter Description Conditions Min Typ 0 – Max Units FGPIO GPIO operating frequency Strong drive 12 MHz TRISE_01 Rise time, ports 0 -1 Strong drive, CLOAD = 50 pF, DVDD = 3.0 - 3.6 50 ns TRISE_01_L Rise time, ports 0 -1, low supply Strong drive, CLOAD = 50 pF, DVDD = 2.7 - 3.0 70 ns TRISE_LDO_3 Rise time, port 1, 3 V LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 3.1 V 50 ns TRISE_LDO_2.5 Rise time, port 1, 2.5 LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 2.7 V 70 ns TRISE_LDO_1.8 Rise time, port 1, 1.8 LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 2.7 V 100 ns TRISE_23 Rise time, ports 2 - 3 Strong drive, CLOAD = 50 pF, DVDD = 2.7 - 3.6 80 ns TFALL Fall time, all ports Strong drive, CLOAD = 50 pF, DVDD = 3.0 - 3.6 50 ns TFALL_L Fall time, all ports, low supply Strong drive, CLOAD = 50 pF, DVDD = 2.7 - 3.0 70 ns TFALL_LDO_3 Fall time, port 1, 3 V LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 3.1 V 50 ns TFALL_LDO_2.5 Fall time, port 1, 2.5 LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 2.7 V 70 ns TFALL_LDO_1.8 Fall time, port 1, 1.8 LDO enabled Strong drive, CLOAD = 50 pF, DVDD > 2.7 V 80 ns Notes 7. IMO can be output from chip by routing to GPIO. Maximum GPIO output frequency is 12 MHz, so duty cycle at 24 MHz is not defined. See Technical Reference Manual at www.cypress.com or in Cypress's PSoC Designer software for details on routing IMO to GPIO pin. 8. Available frequency divisors are 1, 2, 4, 8, 16, 32, 128, and 256. 9. 32 kHz oscillator can be locked to external crystal. See technical reference manual available at www.cypress.com or in Cypress’ PSoC Designer software. 10. Value provided represents maximum startup time for typical application. Applications requiring additional startup code, processing, or delay may increase TMOT. Document Number: 001-44046 Rev. *G Page 19 of 36 [+] Feedback CYONS2100 AC External Clock Specifications The IMO can be replaced with an external clock at the EXT CLK / P[1]4 pin. Refer to the technical reference manual for more details. Table 11 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 11. AC External Clock Specifications Min Typ Max Unit FOSCEXT Parameter Frequency Description 0.750 – 25.2 MHz – High period 20.6 – 5300 ns – Low period 20.6 – – ns – Required time to run from IMO before switching to external clock 150 – – μs AC Analog Mux Bus Specifications The analog mux bus can connect signals from GPIOs to and from internal analog blocks and other GPIOs. Table 12 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 12. AC Analog Mux Bus Specifications Parameter FSW Description Switch rate Conditions Pin voltage < 1.8 V Min Typ Max Unit – – 6.3 MHz AC Programming Specifications Table 13 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 13. AC Programming Specifications Symbol Description Conditions Min Typ Max Units TRSCLK Rise time of ISSP CLK 1 – 20 ns TFSCLK Fall time of ISSP CLK 1 – 20 ns TSSCLK Data setup time to falling rdge of ISSP CLK 40 – – ns THSCLK Data hold time from falling edge of ISSP CLK 40 – – ns FSCLK Frequency of ISSP CLK 0 – 8 MHz TERASEB Flash erase time (Block) – – 18 ms TWRITE Flash block write time – – 25 ms TDSCLK2 Data out delay from falling edge of ISSP CLK – – 85 ns Document Number: 001-44046 Rev. *G 3.0 ≤ DVDD ≤ 3.6 Page 20 of 36 [+] Feedback CYONS2100 AC SPI Specifications Table 14 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 14. AC SPI Master Specifications Min Typ Max Unit fSCLK Parameter SPI CLK frequency[11] Description – – FIMO/2 MHz tSETUP SPI MISO to SPI CLK setup time 60 – – ns tHOLD SPI CLK to SPI MISO hold time 40 – – ns tOUT_SU SPI MOSI to SPI CLK setup time 40 – – ns tOUT_H SPI CLK to SPI MOSI hold time –40 – – ns Min Typ Max Unit – – 12 MHz 41.67 – – ns 41.67 – – ns Table 15. AC SPI Slave Specifications Parameter Description fSCLK SPI CLK frequency[11] tLOW Minimum SPI CLK low width[12] width[12] tHIGH Minimum SPI CLK high tSETUP SPI MOSI to SPI CLK setup time 25 – – ns tHOLD SPI CLK to SPI MOSI hold time 25 – – ns tOUT_H SPI CLK to SPI MISO hold time 35 – – ns tSS_MISO SPI SS to SPI MISO valid – – 100 ns tSCLK_MISO SPI CLK to SPI MISO valid – – 140 ns tSS_HIGH Minimum SPI SS high width – – 35 ns tSS_CLK Time from SPI SS low to first SPI CLK – – 20 ns tCLK_SS Time from last SPI CLK to SPI SS high – – 25 ns Notes 11. Clock frequency is half of clock input to SPI block. 12. Value corresponds to 50% duty cycle at 12 MHz. Document Number: 001-44046 Rev. *G Page 21 of 36 [+] Feedback CYONS2100 Figure 7. SPI Master Timing Diagram, Modes 0 and 2 Figure 8. SPI Master Timing Diagram, Modes 1 and 3 Document Number: 001-44046 Rev. *G Page 22 of 36 [+] Feedback CYONS2100 Figure 9. SPI Slave Timing Diagram, Modes 0 and 2 Figure 10. SPI Slave Timing Diagram, Modes 1 and 3 Document Number: 001-44046 Rev. *G Page 23 of 36 [+] Feedback CYONS2100 AC Comparator Specifications The device includes two general-purpose comparators, using internal or external signals from the analog mux bus. Table 16 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 16. AC Low Power Comparator Specifications Symbol Description TLPC Conditions Comparator response time, 50 mV overdrive 50 mV overdrive does not include offset voltage. Min Typ Max Units – – 100 ns AC I2C Specifications Table 17 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. Table 17. AC Characteristics of the I2C SDA and SCL Pins Symbol Standard Mode Description Fast Mode Units Min Max Min Max 0 100 0 400 kHz FSCLI2C I2C_SCL clock frequency THDSTAI2C Hold time for START and Repeated START condition 4.0 – 0.6 – μs TLOWI2C LOW period of the I2C_SCL clock 4.7 – 1.3 – μs THIGHI2C HIGH period of I2C_SCL clock 4.0 – 0.6 – μs TSUSTAI2C Setup time for a START and Repeated START condition 4.7 – 0.6 – μs THDDATI2C Data hold time 0 – 0 – μs 250 – 100[13] – ns 4.0 – 0.6 – μs 4.7 – 1.3 – μs – – 0 50 ns TSUDATI2C Data setup time TSUSTOI2C Setup time for STOP condition TBUFI2C Bus free time between a STOP and START condition TSPI2C Pulse width of spikes that are suppressed by the input filter Figure 11. Timing for Fast and Standard Mode on the I2C Bus I2C_SDA TSUDATI2C THDSTAI2C TSPI2C THDDATI2CTSUSTAI2C TBUFI2C I2C_SCL THIGHI2C TLOWI2C S START Condition TSUSTOI2C Sr Repeated START Condition P S STOP Condition Note 13. A fast-mode I2C-bus device can be used in a standard mode I2C-bus system, but the requirement tSUDATI2C ≥ 250 ns must then be met. This automatically is the case if the device does not stretch the LOW period of the SCL signal. If such device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line trmax + tSUDATI2C = 1000 + 250 = 1250 ns (according to the standard-mode I2C-bus specification) before the SCL line is released. Document Number: 001-44046 Rev. *G Page 24 of 36 [+] Feedback CYONS2100 AC USB Specifications The device includes an integrated Full-Speed USB block. Table 18 lists guaranteed maximum and minimum specifications for the entire voltage and temperature ranges. S Table 18. AC Characteristics – USB Data Timing Specifications Min Typ Max Units Tdrate Symbol Full speed data rate Description Average bit rate Conditions 12–0.25% 12 12 + 0.25 MHz Tdjr1 Receiver data jitter tolerance To next transition –18.5 – 18.5 ns Tdjr2 Receiver data jitter tolerance To pair transition –9 – 9 ns Tudj1 Driver differential jitter To next transition –3.5 – 3.5 ns Tudj2 Driver differential jitter To pair transition –4.0 – 4.0 ns Tfdeop Source jitter for differential transition To SE0 transition –2 – 5 ns Tfeopt Source SE0 interval of EOP – – 175 ns Tfeopr Receiver SE0 interval of EOP – – Tfst Width of SE0 interval during differential transition – – 14 ns Min Typ Max Units 4 – 20 ns ns Table 19. AC Characteristics – USB Driver Symbol Tr Description Conditions Transition rise time 50 pF Tf Transition fall time 50 pF 4 – 20 ns TR Rise/fall time matching 0.8 V to 2.5 V 90 – 111 % Vcrs Output signal crossover voltage 1.3 – 2.0 V Document Number: 001-44046 Rev. *G Page 25 of 36 [+] Feedback CYONS2100 PCB Land Pads and Keepout Zones Figure 12 and Figure 13 show the recommended land pad architecture and keepout zones. The pads on the 42-pin device are a subset of the JEDEC MO-220 52-pin QFN standard. For detailed layout instructions, see application note AN48995, Mechanical Design Considerations for the OvationONSTM II Laser Navigation System-on-Chip. Figure 12. Land Pad Architecture and Spacing Figure 13. PCB Keep Out Zones Document Number: 001-44046 Rev. *G Page 26 of 36 [+] Feedback CYONS2100 Orientation of Axes Figure 14 describes the relationship between the package and the x/y axes when using the API provided by Cypress’s PSoC Designer software. Note that there is a 90-degree rotation between the orientation below and the orientation described in the register section of the Technical Reference Manual. If PSoC Designer is not used, the application firmware should read and invert the Y count register for X data, and read the X count register for Y data.. Figure 14. Sensor Orientation PCB Mounting Height and Thickness Figure 15 shows the recommended thickness and mounting height of the PCB above the tracking surface. Figure 15. PCB Height and Thickness Document Number: 001-44046 Rev. *G Page 27 of 36 [+] Feedback CYONS2100 Thermal Impedances Table 20. Thermal Impedances per Package Package Typical θJA[14] 42 PQFN[15] 24 °C/W Solder Reflow Peak Temperature Table 21 lists the minimum solder reflow peak temperature needed to achieve good solderability. Table 21. Solder Reflow Peak Temperature Package Minimum Peak Temperature[16] Maximum Peak Temperature 42 PQFN 240°C 260°C Notes 14. TJ = TA + Power x θJA. 15. To achieve the thermal impedance specified for the QFN package, the center thermal pad must be soldered to the PCB ground plane. 16. Higher temperatures may be required based on the solder melting point. Typical temperatures for solder are 220 ± 5°C with Sn-Pb or 245 ± 5°C with Sn-Ag-Cu paste. Refer to the solder manufacturer specifications. For a recommended soldering profile, refer to Application Note 49035, Manufacturing Considerations for the OvationONSTM Laser Navigation System-on-Chip. Document Number: 001-44046 Rev. *G Page 28 of 36 [+] Feedback CYONS2100 Laser Safety Considerations The CYONS2100 laser navigation SoC and the CYONSLENS2000 lens are designed and tested to enable manufacturers to achieve eye safety certification with minimal effort. This section provides guidelines for complying with the Class 1 emission requirements of IEC/EN 60825-1. Laser Output Power Test Procedure When installed and operated in accordance with all requirements in this datasheet, the kit consisting of the CYONS2100 laser navigation SoC and CYONSLENS2000 satisfies CDRH 21 CFR 1040 per Laser Notice 50 and IEC/EN 60825-1 Class 1. Registration Assistance Laser Output Power The CYONS2100 sensor package contains an integrated VCSEL and drive circuitry. Before shipping, Cypress adjusts the laser output power to eye-safe levels, taking into account specified variations in supply voltage, temperature, lens transmission, and VCSEL polarization, and factors such as VCSEL aging and test equipment accuracy. The output remains within eye-safe limits under reasonably foreseeable single-faults, as required by the IEC standard. From the perspective of a manufacturer, laser emission remains within the Class 1 limit, as defined in IEC 60825-1, Edition 2, 2007, provided the following requirements are met. ■ The supply voltage applied to pins DVDD and AVDD of the SoC must be in the range of 2.7 to 3.6 V. ■ The operating temperature must be between 5 and 45 °C. ■ The laser output power must not be increased by any means, including but not limited to firmware, hardware, or mechanical modifications to the sensor or lens. ■ The mechanical housing must be designed such that the CYONSLENS2000 cannot be removed by the user. ■ The device firmware must initialize the VCSEL driver as described in the “VCSEL Driver” chapter of the OvationONS II technical reference manual, or by using the NAV or LaserNAV User Modules in Cypress’s PSoC Designer software. To verify the laser output level, follow the steps shown in the “VCSEL Power Calibration and Verification” section of the technical reference manual. The mouse or end-product supplier is responsible for certifying the end-use product with respect to the drive voltage, manuals and labels, and operating temperature specifications. Additionally, for products sold in the US, a CDRH report must be filed for each model produced, and test and inspection of the product’s characteristics as they relate to laser safety and the CDRH requirements must be performed. When filing a report with the CDRH, the supplier can refer to the product report filed by Cypress for the CYONS2xxx family of products. The Cypress report is based on the previously-noted limits for voltage and temperature, and describes how the sensor design includes consideration of drive circuit failures, laser output variation with temperature, drive circuit variation with temperature and voltage, polarization sensitivity of molded optics, and measurement uncertainties. Cypress can provide assistance to customers who wish to obtain registration. Supporting documentation, including a verification test procedure to demonstrate end-product compliance with IEC and CDRH requirements is available. The manufacturer must ensure that these conditions are always met and demonstrate end-product compliance to the appropriate regulatory standards. Document Number: 001-44046 Rev. *G Page 29 of 36 [+] Feedback CYONS2100 Development Tool Selection This section presents the development tools available for all current PSoC device families including the CYONS2100. Software PSoC Designer At the core of the PSoC development software suite is PSoC Designer, used to generate PSoC firmware applications. PSoC Designer is available free of charge at http://www.cypress.com/psocdesigner and includes a free C compiler with version Service Pack 4.5 or later. Evaluation Tools You can purchase the evaluation tools from the Cypress Online Store. CY3210-MiniProg1 The CY3210-MiniProg1 kit enables a user to program PSoC devices using the MiniProg1 programming unit. The MiniProg is a small, compact prototyping programmer that connects to the PC through a provided USB 2.0 cable. The kit includes: ■ MiniProg programming unit PSoC Programmer ■ MiniEval socket programming and evaluation board Flexible enough to be used on the bench in development, yet suitable for factory programming, PSoC Programmer works either as a standalone programming application or it can operate directly from PSoC Designer. PSoC Programmer software is compatible with both PSoC ICE-Cube In-Circuit Emulator and PSoC MiniProg. PSoC programmer is available free of charge at http://www.cypress.com/psocprogrammer. ■ 28-pin CY8C29466-24PXI PDIP PSoC device sample ■ 28-pin CY8C27443-24PXI PDIP PSoC device sample ■ PSoC Designer software CD ■ Getting Started guide ■ USB 2.0 cable Mouse Design Kits CY3210-PSoCEval1 Two kits featuring the OvationONS II family of products are available. The reference design kit provides a complete hardware, firmware, and software solution, ready for production. The demonstration kit provides tested hardware and firmware that demonstrate the capabilities of the OvationONS II device. The CY3210-PSoCEval1 kit features an evaluation board and the MiniProg1 programming unit. The evaluation board includes an LCD module, potentiometer, LEDs, and plenty of breadboarding space to meet all your evaluation needs. The kit includes: ■ CY4631 wired mouse reference design kit ■ Evaluation board with LCD module ■ Wireless mouse demonstration kit ■ MiniProg programming unit Development Kits ■ 28-pin CY8C29466-24PXI PDIP PSoC device sample (2) You can purchase the development kits from the Cypress Online Store. ■ PSoC Designer software CD ■ Getting Started guide ■ USB 2.0 cable CY3215-DK Basic Development Kit The CY3215-DK kit enables prototyping and development with PSoC Designer. This kit supports in-circuit emulation and the software interface enables users to run, halt, and single step the processor and view the content of specific memory locations. Advance emulation features are also supported through PSoC Designer. The kit includes: CY3214-PSoCEvalUSB ■ PSoC Designer software CD ■ ICE-Cube In-Circuit Emulator The CY3214-PSoCEvalUSB evaluation kit features a development board for the CY8C24794-24LFXI PSoC device. Special features of the board include both USB and capacitive sensing development and debugging support. This evaluation board also includes an LCD module, potentiometer, LEDs, an enunciator and plenty of bread boarding space to meet all your evaluation needs. The kit includes: ■ ICE Flex-Pod for CY8C29x66 family ■ PSoCEvalUSB board ■ Cat-5 adapter ■ LCD module ■ Mini-Eval programming board ■ MIniProg programming unit ■ 110 ~ 240 V power supply, Euro-Plug adapter ■ Mini USB cable ■ iMAGEcraft C compiler (registration required) ■ PSoC Designer and example projects CD ■ ISSP cable ■ Getting Started guide ■ USB 2.0 cable and Blue Cat-5 cable ■ Wire pack ■ Two CY8C29466-24PXI 28-PDIP chip samples Document Number: 001-44046 Rev. *G Page 30 of 36 [+] Feedback CYONS2100 Device Programmers CY3207ISSP In-System Serial Programmer (ISSP) You can purchase the device programmers from the Cypress Online Store. The CY3207ISSP is a production programmer. It includes protection circuitry and an industrial case that is more robust than the MiniProg in a production-programming environment. CY3216 Modular Programmer The CY3216 Modular Programmer kit features a modular programmer and the MiniProg1 programming unit. The modular programmer includes three programming module cards and supports multiple Cypress products. The kit includes: Note CY3207ISSP needs special software and is not compatible with PSoC Programmer. The kit includes: ■ CY3207 programmer unit ■ Modular programmer base ■ PSoC ISSP software CD ■ Three programming module cards ■ 110 ~ 240 V power supply, Euro-Plug adapter ■ MiniProg programming unit ■ USB 2.0 cable ■ PSoC Designer software CD Third Party Tools ■ Getting Started guide ■ USB 2.0 cable Several tools have been specially designed by third-party vendors to accompany PSoC devices during development and production. Specific details for each of these tools are found at http://www.cypress.com. Document Number: 001-44046 Rev. *G Page 31 of 36 [+] Feedback CYONS2100 Package Diagrams Figure 16. QFN Package SIDE VIEW TOP VIEW 0.05 MAX 8.300 SQ 1.40 MAX BOTTOM VIEW 0.50-0.60 [2X] SEE DETAIL - B SEE DETAIL - A ~ ~ 2 Pin 1 0.20 MAX +0.05 0.42-0.00 X 45° [4X] 0.50-0.60 (PIN1 ID) SEATING PLANE +0.025 [2X] Ø0.64 -0.025 THRU DETAIL - A SCALE: 2/1 NOTES: 1. ALL DIMENSIONS ARE IN MM , [ MIN/MAX] 2. REFRENCE JEDEC # MO-220 3. PKG WEIGHT: 0.2 grams +0.025 Ø0.64 -0.025 THRU DETAIL - B 4. APERTURE MOLD CAVITY I .D. 001-44934 *C NON-SOLDERABLE PADS SCALE: 2/1 Document Number: 001-44046 Rev. *G Page 32 of 36 [+] Feedback CYONS2100 Figure 17. Lens 001-44677 *B Ordering Information The CYONS2100 and CYONSLENS2000 are sold separately. When placing orders, order both part numbers. Part Number Package CYONS2100-LBXC 42-pin PQFN CYONSLENS2000-C Lens - 4 mm height Document Number: 001-44046 Rev. *G Application High performance wired Molded optic Page 33 of 36 [+] Feedback CYONS2100 Ordering Code Definition CY ONS XXXX - XXX C Temperature range: Commercial 42- pin PQFN package Wired laser navigation system-on-chip Optical navigation sensor Company ID : CY = Cypress Document Number: 001-44046 Rev. *G Page 34 of 36 [+] Feedback CYONS2100 Document Conventions Numeric Naming Hexadecimal numbers are represented with all letters in uppercase with an appended lowercase ‘h’ (for example, ‘14h’ or ‘3Ah’). Hexadecimal numbers may also be represented by a ‘0x’ prefix, the C coding convention. Binary numbers have an appended lowercase ‘b’ (for example, ‘01010100b’ or ‘01000011b’). Numbers not indicated by an ‘h’, ‘b’, or ‘0x’ are decimal. Acronyms Used Table 22 lists the acronyms used in this document. Units of Measure The units of measure in Table 23 lists the abbreviations used to measure the devices. Table 22. Acronyms Acronym Description Acronym Description AC Alternating Current LDO Low Drop Out (regulator) ADC Analog to Digital Converter LED Light Emitting Diode API Application Programming Interface LPC Low Power Comparator CDRH Center for Devices and Radiological Health LSb Least-significant Bit CPI Counts per Inch LVD Low Voltage Detect CPU Central Processing Unit M8C Cypress’ 8-bit CPU Core DAC Digital to Analog Converter MCU Microcontroller Unit DC Direct Current MIPS Million Instructions per Second DSP Digital Signal Processor MSb Most-significant Bit ESD Electrostatic Discharge MUX Multiplexer GND Ground PC, PCB Printed Circuit, Printed Circuit Board GPIO General Purpose I/O PDIP Plastic Dual In-Line Package HEX Hexadecimal PGA Programmable Gain Amplifier Hi-Z High Impedance POR Power On Reset I2C Inter-Integrated Circuit (bus) PQFN Plastic Quad Flat No-Leads (package) ICE In-circuit Emulator PSoC Programmable System-on-Chip IDAC DAC-Controlled Current Source PSRR Power Supply Rejection Ratio IDE Integrated Development Environment PWM Pulse Width Modulator IEC International Electrotechnical Commission QFN Quad Flat No-Leads (package) ILO Internal Low Speed Oscillator SoC System on Chip IMO Internal Main Oscillator SPI Serial Peripheral Interface (bus) I/O Input/Output SRAM Static Random Access Memory JEDEC Joint Electron Devices Engineering Council USB Universal Serial Bus LCD Liquid Crystal Display VCSEL Vertical Cavity Surface Emitting Laser Table 23. Units of Measure Symbol Unit of Measure Symbol Unit of Measure °C degree Celsius μV microvolts g acceleration of gravity mA milliampere KB 1024 bytes ms millisecond in/s inches per second mV millivolt kHz kilohertz nH nanohenry kΩ kilohm nm nanometer kV kilovolt ns nanosecond MHz megahertz Ω ohm μA microampere pF picofarad μF microfarad pp peak-to-peak μH microhenry V volt μs microsecond W watt Document Number: 001-44046 Rev. *G Page 35 of 36 [+] Feedback CYONS2100 Document History Page Document Title: CYONS2100 OvationONS™ II Wired Gaming Laser Navigation System-on-Chip Document Number: 001-44046 Orig. of Submission Revision ECN Description of Change Change Date ** 2261927 FJZ See ECN CYONS2100 New Data Sheet. *A 2580125 FJZ/PYRS 10/07/08 Extensive Updates *B 2769396 FJZ/AESA 25/09/09 Updated Getting Started and Development Tools sections. Updated thermal impedance, wireless kit part number, Flash specs, storage temperature, I2C footnote, pin table, c compiler information *C 2889331 FJZ 03/09/10 Added Table of Contents. Updated package diagram and Sales links. *D 2903558 FJZ 04/20/10 Update LVD, USB, SPI Master and SPI Slave specs, numerous minor updates for improved clarity and consistency *E 2936335 MMCY 05/24/2010 Updated content to match the new template and style guide. No technical updates. *F 3092209 FJZ 11/22/2010 Corrected error in Pin Description. Removed invalid reference to application note in Registration Assistance. *G 3126503 FJZ 01/03/2011 Updated Figure 17. Changed posting to external web Sales, Solutions, and Legal Information Worldwide Sales and Design Support Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office closest to you, visit us at Cypress Locations. Products Automotive Clocks & Buffers Interface Lighting & Power Control PSoC Solutions cypress.com/go/automotive psoc.cypress.com/solutions cypress.com/go/clocks PSoC 1 | PSoC 3 | PSoC 5 cypress.com/go/interface cypress.com/go/powerpsoc cypress.com/go/plc Memory Optical & Image Sensing PSoC Touch Sensing USB Controllers Wireless/RF cypress.com/go/memory cypress.com/go/image cypress.com/go/psoc cypress.com/go/touch cypress.com/go/USB cypress.com/go/wireless © Cypress Semiconductor Corporation, 2008-2011. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges. Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign), United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of, and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without the express written permission of Cypress. Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges. Use may be limited by and subject to the applicable Cypress software license agreement. Document Number: 001-44046 Rev. *G Revised January 3, 2011 Page 36 of 36 OvationONS™, OptiCheck™, and PSoC Designer™ are trademarks and PSoC and CapSense are registered trademarks of Cypress Semiconductor Corp. All other trademarks or registered trademarks referenced herein are property of the respective corporations. [+] Feedback