PSo C 3 and PSo C 5 LP

PSo. C 3 and PSo. C 5 LP For Temperature Sensing Reduce Your Manufacturing Cost and Time-to-Market Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Presentation: To provide an engineering overview to customers for a Cypress solution. Title slide: To define what the presentation will cover. The subtitle is a one-sentence statement of the key opportunity. 001 -76565 Rev *H

Re-engineering Temperature Sensing Every sensor requires a special analog IC, which adds cost Companies are re-engineering older products to reduce cost Replacing older analog ICs as they become obsolete Consolidating platforms to reduce PCB variants Designing new products in smaller enclosures This is a great opportunity to reduce your BOM, manufacturing cost, and time-to-market for your product portfolio Temperature Sensors, each with its special analog IC Diode TI TMP 431 $0. 55 RTD Thermistor Maxim MAX 6682 $1. 82 Thermocouple Temperature Controllers: End-product variants require multiple PCBs ADI AD 7792 $4. 04 ADI REF 192 $2. 01 TI LMP 90078 $2. 45 Microchip Microcontroller $2. 94 Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Market Vision: To define the market opportunity. Presents compelling data and end product photos relevant to the local market. Should use compelling photographs of actual PSo. C products. 3

Terms You Will Hear Today Temperature Sensors − convert temperature to an analog signal Thermocouple (e. g. , type K, J, T): generates ~40 µV/ o. C, requires ADC and a reference Temperature Sensor RTD (Resistance Temperature Detector): changes ~0. 387 Ω/ °C, requires current source and ADC Thermistor: changes ~400 Ω/ °C at room temperature, requires voltage source and ADC Temperature diode: ~250 µV/ o. C, requires current source and ADC Current/Voltage Sources for Sensors ICs that generate precise voltage or current supplies for sensors IDAC (Current Output Digital to Analog Converter) IC that generates programmable current sources for sensors ADC (Analog to Digital Converter) IC that converts analog sensor signals, such as Temperature Sensor outputs, to digital for a microcontroller AFE (Analog Front End) IC that integrates ADC and either a current or voltage source Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Terms of Art (To. As): To clearly define tor engineers all To. As used in the presentation. To carefully and fully define Cypress-proprietary To. As needed to explain our system solution. 4 a

PSo. C Terms 100+ other Components to complete the system design PSo. C® Creator™ PSo. C 3 and PSo. C 5 LP Integrated Design Environment (IDE) Software that installs on your PC Allows concurrent hardware/firmware design of PSo. C systems Components Free “Virtual ICs” represented by an icon in PSo. C Creator software Used to integrate multiple ICs and system interfaces into one PSo. C Dragged and dropped as icons to design systems in PSo. C Creator Inherently connected to MCU via the main system bus Sensor Components automatically convert ADC output to temperature with sophisticated algorithms and excellent accuracy Component Configuration Tools Simple Graphical User Interfaces in PSo. C Creator Embedded in each Component Used to customize Component parameters Launched by right-clicking a Component ADC Component Icon The ADC Component integrates from 8 -bits to 20 -bits ADC ICs Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Analog Components integrate analog ICs Sensor Components: RTD, Thermistor, and Thermocouple MCU Inherent system bus connection The colored header on Component icons signifies system bus connection Terms of Art (To. As): To clearly define for engineers all To. As used in the presentation. To carefully and fully define Cypress-proprietary To. As needed to explain our system solution. 4 b

Design Problems Engineers Face 1. Temperature-sensing system requires multiple ICs ($) AFEs for each sensor A microcontroller with firmware algorithms to convert and correct sensor outputs and to communicate the temperature to other devices (e. g. , displays) 2. Multiple-sensor interface design is complicated Single-IC obsolescence may cause redesign PCB designs change every time a chip or wire changes Sourcing ICs from multiple vendors complicates and slows development 3. Fitting products into small enclosures is challenging Multiple ICs require larger PCBs Multiple AFE ICs PSo. C overcomes these three problems PSo. C one-chip solution supports multiple Temperature Sensors (simultaneously) PSo. C Sensor Components provide algorithms and firmware for accurate sensor conversion PSo. C integrates the microcontroller and analog ICs with ADC and IDAC Components PSo. C enables fast, easy design modifications without PCB changes Each design has different ICs and PCBs PSo. C simplifies design by integrating many ICs in a single chip PSo. C reduces PCB size and PCB layers, enabling smaller enclosures PSo. C is an easy-to-use, low-cost, one-chip temperature-sensing solution Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Traditional Approach and Challenges: To present the traditional approach and the challenges engineers will face when using it to realize the Market Vision. Ends with a one-sentence segue clearly stating the benefit of the Cypress solution. 5

PSo. C One-Chip Solution Thermocouple Thermistor (internal) Connect LED display Precision Analog Sensor Kit Thermistor Thermocouple PSo. C 3 Kit Temperature controllers require multiple PCBs RTD Complex Temperature Sensor designs with many analog ICs… Are integrated as PSo. C Creator Components to create system designs… To get started, you should: That are prototyped and validated using the PSo. C 3 Kit… RTD And programmed into a single PSo. C to create multiple end products. Actual Temperature Controller design by Cell System Buy $99 Precision Analog Sensor Kit (CY 8 CKIT-025) Buy $99 PSo. C 3 Kit (CY 8 CKIT-030) or PSo. C 5 LP Kit (CY 8 CKIT-050) Install PSo. C Creator software and Precision Analog Sensor Kit on your PC Open and work with multiple temperature-sensing Example Projects Use your sensor specific (e. g. , RTD) App Note for complete system design guidelines Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Cypress Solution: Compelling CY Creator introduction to solve the challenges highlighted on the previous slide. Provides a short, clear list of what to do to get started. 6 a

System Design in PSo. C Creator IDE Multiple-sensor Example Project in PSo. C Creator IDE 1. Explore the library of 100+ Components 2. Drag and drop Component icons to complete your hardware system design in the main design workspace 3. Configure Components using the Component Configuration Tools 4. Access Component datasheets with technical specifications directly from the Component Configuration Tools 5. Codesign your application firmware with the PSo. C hardware using the PSo. C Creator IDE C compiler 6. Use included sensor specific App Notes for complete system design guidelines Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Cypress Solution: Compelling CY Creator introduction to solve the challenges highlighted on the previous slide. Provides a short, clear list of what to do to get started. 6 b

Upgrading RTD Sensing OLD: Traditional RTD Solution with 0. 1% accuracy NEW: PSo. C RTD Solution with 0. 1% accuracy DAC with current output Discrete ICs ADC with integrated voltage reference and amplifier ADC output goes to RTD Component Traditional RTD solution requires 6 ICs OLD: Typical MCU code needed for RTDs 100+ lines of code Engineering Presentation Owner: GDK Rev *H Tech lead: GDK NEW: PSo. C Creator RTD Component and Configuration Tool RTD Component converts ADC output to accurate temperature with embedded algorithm library Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 c

PSo. C RTD Sensing Solution Create your RTD solution in minutes Download App Note AN 70698 – Temperature Measurement with RTDs Use the provided Example Project as a starting point (includes ADC and IDAC Components) Configure the RTD Component based on your sensor type (PT 100, PT 500, PT 1000) and temperature range Select temperature calculation error budget vs. instruction cycles requirement Design the remainder of your system in PSo. C Creator Build your project and prototype your system using the Precision Analog Sensor Kit RTD Component Configuration Tool Select RTD type, temperature range and calculation error budget; view temperature calculation error vs. temperature Engineering Presentation Owner: GDK Rev *H Tech lead: GDK PSo. C RTD Solution for broken-wire reconfiguration Mechanical stress causes one of four wires to break PSo. C autoreconfigures to three-wire mode Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 d

Upgrading Thermocouple Sensing OLD: Traditional thermocouple solution with 0. 1% accuracy NEW: PSo. C thermocouple solution with 0. 1% accuracy ADC with integrated voltage reference and amplifier Discrete ICs ADC output goes to Sensor Components that automatically convert to temperature Traditional thermocouple solution requires 7 ICs OLD: Typical MCU code needed for thermocouples 500+ lines of code Engineering Presentation Owner: GDK Rev *H Tech lead: GDK NEW: Thermocouple Component and Configuration Tool Thermocouple Component converts ADC output to accurate temperature with ninth-order polynomial Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 e

PSo. C Thermocouple Sensing Solution Create your Thermocouple Solution in minutes Download App Note AN 75511 – Temperature Measurement with Thermocouples Use the provided Example Project as a starting point (includes thermistor circuit for cold junction compensation) Choose thermocouple type (J, K etc. ) in Component Configuration Tool Choose temperature calculation error budget vs. instruction cycles requirement for thermocouple Enter thermistor resistance at three temperatures in Thermistor Component Configuration Tool (for cold junction compensation) Select calculation implementation method for thermistor based on instruction cycles vs. accuracy requirements Design the remainder of your system in PSo. C Creator Build your project and prototype your system using the Precision Analog Sensor Kit Thermocouple Component Configuration Tool Choose thermocouple type, calculation error budget; view temperature calculation error vs. temperature Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Thermistor Component Configuration Tool Select implementation method Configure thermistor parameters Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 f

Example Project with Multiple Sensors Example Project from the Precision Analog Sensor Kit with five Temperature Sensors 1. Current and voltage source for Temperature Sensors 2. Five Temperature Sensors with only passives external to PSo. C 3. Multi-channel differential 20 -bit ADC reading all Temperature Sensors 4. Sensor Components automatically convert ADC output to temperature 5. Cap. Sense user interface and LCD display to select sensor to display and to calibrate sensors Watch the demo video: www. cypress. com/go/CY 8 CKIT-025 Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 g

Prototype Your Solution Use the Precision Analog Sensor Kit (CY 8 CKIT-025) Connect to your PSo. C 3 Kit (CY 8 CKIT-030) or PSo. C 5 LP Kit (CY 8 CKIT-050) Select from four provided sensors: RTD, thermocouple, thermistor or diodes Or attach your own sensor using on-board connectors Use any other sensor to measure cold-junction temperature for thermocouple Use Cap. Sense touch buttons to implement user interface Validate your custom solution for temperature sensing Watch our demo video: www. cypress. com/go/CY 8 CKIT-025 PSo. C 3 Kit (CY 8 CKIT-030) Cap. Sense buttons select sensor to display Precision Analog Sensor Kit (CY 8 CKIT-025) Thermocouple Input Diode Inputs PSo. C 3 Kit connector Thermistor (on board) Thermistor (ext input) Engineering Presentation Owner: GDK Rev *H Tech lead: GDK RTD (ext input) RTD (on board) Cypress Solution: To introduce CY products and show compellingly how they solve the challenges highlighted on the previous slide. To provide a short, clear list of what to do to get started. 6 h

PSo. C® Solution Example – RTD Temperature Sensing with CAN Block Diagram PSo. C Value Design Challenges Support 10 RTDs, each with four wires Provide auto-reconfiguration for broken wire Offer high reliability to operate remote equipment Reduce PCB size PSo. C Solution Supports 10 four-wire RTDs in a single PSo. C Detects RTD broken wire and provides auto reconfiguration Increases reliability with lower chip count Integrates 12 ICs into PSo. C one-chip solution PSo. C One-Chip Solution M U X Integrated Analog Components IDAC UART (RS 485) 8051 MCU 10 RTDs M U X ADC + PGA RTD CAN 8 Suggested Collateral FLASH App Notes: RTD, CAN Interface Kits: Precision Analog Sensor Kit (CY 8 CKIT-025) PSo. C 3 Kit (CY 8 CKIT-030) SRAM DMA PSo. C Creator Components RTD (converts ADC output to temperature) ADC (16 -bit Delta Sigma ADC with PGA) IDAC (programmable current source) MUX (Analog Multiplexer) DMA (Direct Memory Access between ADC and CAN module) CAN (communicate with host module) UART (communicate with external modules) Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Windmills by Vestas With 10 -sensor temperature measurement Solution Examples: To give detailed one-page PSo. C Solution Examples from the field in the specified format. 7 a

PSo. C® Solution Example – Temperature I/O Module with Custom UART Block Diagram PSo. C Value Design Challenges Eliminate level shifter IC Support customized UART Support multiple Temperature Sensors Achieve higher system reliability PSo. C Solution Eliminates level shifter IC with 5 -V I/O Enables customized UART eliminating external CPLD Simplifies multiple-sensor design with integrated AFE Improves reliability by reducing chip count PSo. C One-Chip Solution IDAC ARM Cortex-M 3 MCU RTD VREF Thermocouple M U X ADC +PGA Suggested Collateral Thermocouple Customized UART in PLD UART RTD 8 App Notes: RTD, Thermocouple, Thermistor, Diode Kits: Precision Analog Sensor Kit (CY 8 CKIT-025) PSo. C 5 LP Kit (CY 8 CKIT-050) PSo. C Creator Components Thermocouple (converts ADC output to temperature) RTD (converts ADC output to temperature) ADC (16 -bit Delta Sigma ADC with PGA) MUX (Analog Multiplexer) IDAC (programmable current source) UART (customized UART in PLD) Logic Gates (customized UART in PLD) Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Integrated Analog Components Voltage input FLASH SRAM DMA I/O Module by Unimat Converts temperature and voltage inputs to digital data for Programmable Logic Controller used in plant automation Solution Examples: To give detailed one-page PSo. C Solution Examples from the field in the specified format. 7 b

PSo. C® Solution Example – Special Purpose Temperature Controller Block Diagram PSo. C Value Design Challenges Provide temperature control with four Peltier modules Support multiple types of Temperature Sensors Achieve higher system reliability and safety PSo. C Solution Integrates 18 ICs into one-chip solution for temperature control with four Peltier modules Simplifies multiple-sensor design with integrated AFE Enables hardware current limiting for protection PSo. C One-Chip Solution M U X Peltier modules with Temperature Sensors 2 x Thermocouples 4 Current PSo. C Creator Components Sense RSENSE H-Bridge Thermocouple (converts ADC output to temperature) RTD (converts ADC output to temperature) ADC (16 -bit Delta Sigma ADC with PGA) IDAC (programmable current source) CAN (communication interface) UART (communication interface) Engineering Presentation Owner: GDK Rev *H Tech lead: GDK PWM#2 4 Current PWM#1 VREF 8051 MCU ADC + PGA Thermocouple RTD 4 x Output to Peltier Module Sense App Notes: Diode, Thermocouple, RTD Kits: Precision Analog Sensor Kit (CY 8 CKIT 025) PSo. C 3 Kit (CY 8 CKIT-030) M U X Peltier Element PWM#1 Suggested Collateral IDAC 2 x RTDs 4 x Integrated Analog Components PWM#2 Op Amp Op 4 x Amp 4 x Comparator VREF 8 Current Sense Current Limiting PWM CAN 8 UART DMA FLASH PLD 4 x Temperature Controller by Cell System Controls four Peltier modules that convert power into heating or cooling Solution Examples: To give detailed one-page PSo. C Solution Examples from the field in the specified format. 7 c

PSo. C® Solution Example – Refrigeration Control System PSo. C Value Block Diagram Design Challenges Support 22 temperature sensing inputs Enable simultaneous sensing of two or more inputs Support multiple types of Temperature Sensors Current sources for RTD sensing PSo. C Solution Supports 22 inputs with multiple ADCs and current sources Enables simultaneous sensing using multiple ADCs Simplifies multiple-sensor design with integrated AFE App Notes: RTD, Thermocouple, Thermistor Kits: Precision Analog Sensor Kit (CY 8 CKIT-025) PSo. C 5 LP Kit (CY 8 CKIT-050) M U X SAR ADC ARM Cortex-M 3 MCU 32 Thermocouple +SAR ADC 4 To Other System Modules VREF M U X ∆ ∑ ADC +PGA Thermistor PSo. C Creator Components Engineering Presentation Owner: GDK Rev *H Tech lead: GDK SPI RTD VREF Thermocouple (converts ADC output to temperature) RTD (converts ADC output to temperature) Thermistor (converts ADC output to temperature) ADC (12 -bit SAR ADC) ADC (16 -bit Delta Sigma ADC with PGA) MUX (Analog Multiplexer) SPI (8 -Mbps interface to host processor) IDAC (programmable current source) Integrated Analog Components IDAC VREF 22 Temperature Inputs Suggested Collateral PSo. C One-Chip Solution 32 FLASH Refrigeration Control Unit Monitors temperature inside shipping containers Solution Examples: To give detailed one-page PSo. C Solution Examples from the field in the specified format. 7 d

PSo. C® Solution Example – I/O Expander for HVAC Control System PSo. C Value Block Diagram Design Challenges Support 20 analog input measurements Provide 8 analog outputs and 16 digital outputs Provide option for future memory expansion PSo. C Solution Supports 20 analog inputs at 16 -bit resolution Supports 8 analog outputs at 8 -bit resolution and 16 digital outputs Provides External Memory Interface for future memory expansion Suggested Collateral App Note: Thermistor Kits: Precision Analog Sensor Kit (CY 8 CKIT-025) PSo. C 5 LP Kit (CY 8 CKIT-050) PSo. C Creator Components Thermistor (converts ADC output to temperature) ADC (16 -bit Delta Sigma ADC with PGA) VDAC (Voltage output Digital to Analog Converter) MUX (Analog Multiplexer) CAN (communication interface with external modules) EMIF (External Memory Interface for future expansion) Engineering Presentation Owner: GDK Rev *H Tech lead: GDK PSo. C One-Chip Solution To thermistor Inputs M U X Op Amp VREF ARM Cortex-M 3 MCU 20 Analog Inputs (Temperature, 4 -20 m. A Current Loop) VREF M U X ADC + PGA Integrated Analog Components VDAC 4 4 x LOW PASS FILTER 4 PWM 4 x Thermistor 4 x 16 UART 32 FLASH EMIF 8 Analog Outputs 16 Digital Outputs To External Modules DMA I/O Expander for HVAC (Heating, Ventilation and Air Conditioning) Control System Used for home automation and temperature control Solution Examples: To give detailed one-page PSo. C Solution Examples from the field in the specified format. 7 e

PSo. C Solution vs. Competition’s Precision Analog Sensor Kit Connected to PSo. C 3 Kit TI / National AFE Expansion Kit and Microcontroller interface board PSo. C 3 Kit Thermocouple Input AFE Expansion Kit Microcontroller interface board 3 Diodes Thermistor (on-board or external input) 2 1 4 RTD (on-board or external input) Single-chip PSo. C 3 solution reading Thermocouple 1 Four ICs from three different vendors Cap. Sense buttons select sensor to display Cypress PSo. C 3 TI AFE and microcontroller Chips Required for Temperature Controller 1 4 Number of Sensor Inputs 1 to 61 1 to 7 Number of Current/Voltage Sensor Sources Up to 4 sources Up to 2 sources Graphical Design Tool Yes AFE only Complete System Example Projects Yes No Kit Price $198 $248 Feature Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Competitive Comparison: To define key features of the Cypress solution and demonstrate its superiority over NBA(s). Must be credible and objective to the salesperson and customer. 8

PSo. C 3 Temperature Sensing Solution Value Competitor $2. 45 Sensor AFE IC: TI Multi-Channel, Low-Power 16 -bit AFE LMP 90078 Price: $2. 45 Voltage Reference IC $0. 78 BOM Integration Voltage Reference IC: TI LM 4132 B Price: $0. 78 Analog MUX IC: On Semi MC 14067 (16: 1) Price: $1. 00 MCU IC: Microchip PIC 18 F 85 K 90 (100 -pin, 32 K Flash, LCD drive, 5 V) Price: $2. 94 $1. 00 $2. 94 BOM Integration Value $4. 72 Total Value Delivered $7. 17 Target PSo. C Solution: CY 8 C 3865 AXI-204 Total Cost: $6. 03 16% Total Savings: $1. 14 All pricing 1 Ku from supplier website Engineering Presentation Owner: GDK Rev *H Tech lead: GDK EVC Slide: To clearly define the value of the Cypress solution, including BOM integration and unique functionality. 9

Here’s How to Get Started 1. View our demo videos: www. cypress. com/go/CY 8 CKIT-025 2. Download your sensor specific App Note: www. cypress. com/go/Temp. Sense 3. Buy the Precision Analog Sensor Kit and PSo. C 3 Kit or PSo. C 5 LP Kit www. cypress. com/go/CY 8 CKIT-030 (CY 8 CKIT-030) $99 www. cypress. com/go/CY 8 CKIT-050 (CY 8 CKIT-050) $99 www. cypress. com/go/CY 8 CKIT-025 (CY 8 CKIT-025) $99 I/O Module by Unimat 10 -sensor temperature measurement Converts temperature and voltage inputs to digital data for Programmable Logic Controller used in plant automation Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Windmills by Vestas Special Purpose Temperature Controllers by Cell System Temperature Transducer Controls four Peltier modules that convert power into heating or cooling Measures temperature and communicates information over 4 -20 m. A or HART protocol Call to Action: To tell salespeople how to proceed. To ask them to volunteer account names, to schedule joint account visits, to use the scripted email, and to set up a demo. 11

References and Links Demo Videos: www. cypress. com/go/tempsense Demonstrates Precision Analog Sensor Kit operation and accuracy measurement Precision Analog Sensor Kit (CY 8 CKIT-025) Page: www. cypress. com/go/CY 8 CKIT-025 Contains kit documentation and three Example Projects for multi-sensor designs PSo. C 3 Kit (CY 8 CKIT-030) Page: www. cypress. com/go/CY 8 CKIT-030 PSo. C 5 LP Kit (CY 8 CKIT-050) Page: www. cypress. com/go/CY 8 CKIT-050 Temperature Sensing and Control application page: www. cypress. com/go/tempsense Contains links to all temperature sensing related collateral from Cypress App Note AN 75511 for Thermocouple: www. cypress. com/? r. ID=60544 App Note AN 70698 for RTD: www. cypress. com/? r. ID=57546 App Note AN 66477 for Thermistor: www. cypress. com/? r. ID=49052 App Note AN 60590 for Diode: www. cypress. com/? r. ID=42993 App Note AN 66444 for offset cancellation technique: www. cypress. com/? r. ID=49159 App Note AN 65977 for TMP 05 / TMP 06 digital sensor: www. cypress. com/? r. ID=48490 App Note AN 66627 for Intelligent Fan Controller: www. cypress. com/? r. ID=49077 Engineering Presentation Owner: GDK Rev *H Tech lead: GDK Other available materials: Provide distributors with comprehensive view of resources to assist in selling the solution. 13