CY8C9520A CY8C9540A, CY8C9560A 20, 40, and 60 Bit I/O Expander with EEPROM Features Overview 2 ■ I C interface logic electrically compatible with SMBus ■ Up to 20 (CY8C9520A), 40 (CY8C9540A), or 60 (CY8C9560A) I/O data pins independently configurable as inputs, outputs, Bi-directional input/outputs, or PWM outputs ■ 4/8/16 PWM sources with 8-bit resolution ■ Extendable soft addressing algorithm allowing flexible I2C address configuration ■ Internal 3-/11-/27-Kbyte EEPROM ■ User default storage, I/O port settings in internal EEPROM ■ Optional EEPROM write disable (WD) input ■ Interrupt output indicates input pin level changes and pulse width modulator (PWM) state changes ■ Internal power on reset (POR) ■ Internal configurable watchdog timer EEPROM User Settings Area User Available Area Clocks 32 kHz GPort 0 8 Bit IO GPort 1 5 Bit IO 3 Bit IO or A4-A6 GPort 2 4 Bit IO or A1-A3, WD6 GPort 3 8 Bit IO GPort 7 8 Bit IO 24 MHz 1.5 MHz 93.75 kHz Divider (1-255) PWM 0 Control Unit PWM 15 SCL INT SDA V dd Power-on-Reset A0 V ss Cypress Semiconductor Corporation Document Number: 38-12036 Rev. *E The CY8C95xxA operates as two I2C slave devices. The first device is a multi port I/O expander (single I2C address to access all ports through registers). The second device is a serial EEPROM. Dedicated configuration registers can be used to disable the EEPROM. The EEPROM uses 2-byte addressing to support the 28 Kbyte EEPROM address space. The selected device is defined by the most significant bits of the I2C address or by specific register addressing. The I/O expander's data pins can be independently assigned as inputs, outputs, quasi-bidirectional input/outputs or PWM ouputs. The individual data pins can be configured as open drain or collector, strong drive (10 mA source, 25 mA sink), resistively pulled up or down, or high impedance. The factory default configuration is pulled up internally. The system master writes to the I/O configuration registers through the I2C bus. Configuration and output register settings are storable as user defaults in a dedicated section of the EEPROM. If user defaults were stored in EEPROM, they are restored to the ports at power up. While this device can share the bus with SMBus devices, it can only communicate with I2C masters. The I2C slave in this device requires that the I2C master supports clock stretching. Top Level Block Diagram WD The CY8C95xxA is a multi-port I/O expander with on board user available EEPROM and several PWM outputs. All devices in this family operate identically but differ in I/O pins, number of PWMs, and internal EEPROM size. There is one dedicated pin that is configured as an interrupt output (INT) and can be connected to the interrupt logic of the system master. This signal can inform the system master that there is incoming data on its ports or that the PWM output state was changed. The EEPROM is byte readable and supports byte-by-byte writing. A pin can be configured as an EEPROM Write Disable (WD) input that blocks write operations when set high. The configuration registers can also disable EEPROM operations. The CY8C95xxA has one fixed address pin (A0) and up to six additional pins (A1-A6), which allow up to 128 devices to share a common two wire I2C data bus. The Extendable Soft Addressing algorithm provides the option to choose the number of pins needed to assign the desired address. Pins not used for address bits are available as GPIO pins. There are 4 (CY8C9520A), 8 (CY8C9540A), or 16 (CY8C9560A) independently configurable 8-bit PWMs. These PWMs are listed as PWM0-PWM15. Each PWM can be clocked by one of six available clock sources. For details on how to configure I2C, see Application Note "Communication - I2C Port Expander with Flash Storage AN2304" at http://www.cypress.com. • 198 Champion Court • San Jose, CA 95134-1709 •408-943-2600 Revised December 14, 2010 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Contents Architecture .............................................................3 Applications ........................................................3 Device Access Addressing ....................................4 Serial EEPROM Device ......................................4 Multi Port I/O Device ...........................................4 Document Conventions ..........................................4 Acronyms ............................................................4 Units of Measure ................................................4 Numeric Naming .................................................4 Pinouts .....................................................................5 28-Pin Part Pinout ..............................................5 48-Pin Part Pinout ..............................................6 100-Pin Part Pinout ............................................7 Pin Descriptions ......................................................9 Extendable Soft Addressing ...............................9 Interrupt Pin (INT) ...............................................9 Write Disable Pin (WD) .......................................9 External Reset Pin (XRES) .................................9 Working with PWMs ...........................................9 Register Mapping Table ........................................11 Register Descriptions ...........................................11 Input Port Registers (00h - 07h) .......................11 Output Port Registers (08h - 0Fh) ....................11 Int. Status Port Registers (10h - 17h) ...............12 Port Select Register (18h) ................................12 Interrupt Mask Port Register (19h) ...................12 Select PWM Register (1Ah) ..............................12 Inversion Register (1Bh) ...................................12 Port Direction Register (1Ch) ...........................12 Drive Mode Registers (1Dh-23h) ......................12 PWM Select Register (28h) ..............................12 Config (29h) ......................................................13 Period Register (2Ah) .......................................13 Pulse Width Register (2Bh) ..............................13 Document Number: 38-12036 Rev. *E Divider Register (2Ch) ......................................13 Enable Register (2Dh) ......................................13 Device ID/Status Register (2Eh) .......................13 Watchdog Register (2Fh) .................................14 Command Register (30h) .................................14 Commands Description ........................................14 Store Config to E2 POR Defaults Cmd (01h) ...14 Restore Factory Defaults Cmd (02h) ................14 Write E2 POR Defaults Cmd (03h) ...................14 Read E2 POR Defaults Cmd (04h) ...................15 Write Device Config Cmd (05h) ........................15 Read Device Config Cmd (06h) ........................15 Reconfigure Device Cmd (07h) ........................15 Electrical Specifications .......................................16 Absolute Maximum Ratings ..............................16 Operating Temperature ....................................16 DC Electrical Characteristics ............................17 AC Electrical Characteristics ............................19 Packaging Dimensions .........................................21 Thermal Impedances ........................................23 Solder Reflow Peak Temperature ....................23 Features and Ordering Information .....................24 Ordering Code Definitions ................................24 Acronyms ...............................................................25 Reference Documents ..........................................25 Document Conventions ........................................25 Units of Measure ..............................................25 Numeric Conventions .......................................25 Glossary .................................................................26 Document History Page ........................................31 Sales, Solutions, and Legal Information .............32 Worldwide Sales and Design Support ..............32 Products ...........................................................32 PSoC Solutions ................................................32 Page 2 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Architecture Figure 1. Logical Structure of the I/O Port The Top Level Block Diagram on page 1 illustrates the device block diagram. The main blocks include the control unit, PWMs, EEPROM, and I/O ports. The control unit executes commands received from the I2C bus and transfers data between other bus devices and the master device. The on chip EEPROM can be separated conventionally into two regions. The first region is designed to store data and is available for byte wide read/writes through the I2C bus. It is possible to prevent write operations by setting the WD pin to high. All EEPROM operations can be blocked by configuration register settings. The second region allows the user to store the port and PWM default settings using special commands. These defaults are automatically reloaded and processed after device power on. GPortx 7 Drive Mode Registers DriveMode Pull-Up Output Register Data PWMs DriveMode High Z Select PWM The number of I/O lines and PWM sources are listed in the following table. Interrupt Status Table 1. GPIO Availability Port CY8C9520A CY8C9540A CY8C9560A GPort 0 8 bit 8 bit 8 bit GPort 1 5-8 bit[1] 5-8bit[1] 5-8 bit[1] GPort 2 0-4 bit[1] 0-4it[1] 0-4 bit[1] GPort 3 – 8 bit 8 bit GPort 4 – 8 bit 8 bit GPort 5 – 4 bit 8 bit GPort 6 – – 8 bit GPort 7 – – 8 bit PWMs 4 8 16 There are four pins on GPort 2 and three on GPort 1 that can be used as general purpose I/O or EEPROM Write Disable (WD) and I2C-address input (A1-A6), depending on configuration settings. Figure 1 shows the single port logical structure. The Port Drive Mode register gives the option to select one of seven available modes for each pin separately: pulled up/down, open drain high/low, strong drive fast/slow, or high impedance. By default these configuration registers store values setting I/O pins to be pulled up. The Invert register enables inversion of the logic of the Input registers separately for each pin. The Select PWM register assigns pins as PWM outputs. All of these configuration registers are read/writable using corresponding commands in the multi-port device. Input Register 8 Bit IO Interrupt Mask Pin Direction Inversion The Port Input and Output registers are separated. When the Output register is written, the data is sent to the external pins. When the Input register is read, the external pin logic levels are captured and transferred. As a result, the read data can be different from written Output register data. This enables implementation of a quasi-bidirectional input-output mode, when the corresponding binary digit is configured as pulled up/down output. Each port has an Interrupt Mask register and an Interrupt Status register. Each high bit in the Interrupt Status register signals that there has been a change in the corresponding input line since the last read of that Interrupt Status register. The Interrupt Status register is cleared after each read. The Interrupt Mask register enables/disables activation of the INT line when input levels are changed. Each high in the Interrupt Mask register masks (disables) an interrupt generated from the corresponding input line. Applications Each GPIO pin can be used to monitor and control various board level devices, including LEDs and system intrusion detection devices. The on board EEPROM can be used to store information such as error codes or board manufacturing data for read-back by application software for diagnostic purposes. Note 1. This port contains configuration-dependant GPIO lines or A1-A6 and WD lines. Document Number: 38-12036 Rev. *E Page 3 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Device Access Addressing space is reached, then further writes are responded to with a NAK. Following a start condition, the I2C master device sends a byte to address an I2C slave. This address accesses the device in the CY8C95xx. By default there are two possible address formats in binary representation: 010000A0X and 101000A0X. The first is used to access the multi port device and the second to access the EEPROM. If additional address lines (A1-A6) are used then the Device Addressing. Table 2 defines the device addresses. This addressing method uses a technique called Extendable Soft Addressing, described in the section Extendable Soft Addressing on page 9. Multi Port I/O Device This device allows the user to set configurations and I/O operations through internal registers. Each data transfer is preceded by the command byte. This byte is used as a pointer to a register that receives or transmits data. Available registers are listed in Table 7 on page 11. Document Conventions Table 2. Device Addressing Multi-Port Device 01 Refer to Figure 6 on page 10, which illustrates memory reading and writing procedures for the EEPROM device. EEPROM Device 0 0 0 0 A0 R/W 1 0 1 0 0 0 A0 R/W 0 0 A1 A0 R/W 1 0 1 0 0 A1 A0 R/W 0 1 0 0 1 0 0 A2 A1 A0 R/W 1 0 1 0 A2 A1 A0 R/W 0 1 0 A3 A2 A1 A0 R/W 1 0 1 A3 A2 A1 A0 R/W 0 1 A4 A3 A2 A1 A0 R/W 1 0 A4 A3 A2 A1 A0 R/W 0 A5 A4 A3 A2 A1 A0 R/W 1 A5 A4 A3 A2 A1 A0 R/W A6 A5 A4 A3 A2 A1 A0 R/W A6 A5 A4 A3 A2 A1 A0 R/W When all address lines A1-A6 are used, the device being accessed is defined by the first byte following the address in the write transaction. If the most significant bit (MSb) of this byte is ‘0’, this byte is treated as a command (register address) byte of the multi-port device. If the MSb is ‘1’, this byte is the first of a 2-byte EEPROM address. In this case, the device masks the MSb to determine the EEPROM address. Serial EEPROM Device EEPROM reading and writing operations require 2 bytes, AHI and ALO, which indicate the memory address to use. To read one or more bytes, the master device addresses the unit with a write cycle (= 0) to send AHI followed by ALO, readdresses the unit with a read cycle (= 1), and reads one or more data bytes. Each data byte read increments the internal address counter by one up to the end of the EEPROM address space. A read or write beyond the end of the EEPROM address space must result in a NAK response by the Port Expander. To write data to the EEPROM, the master device performs one write cycle, with the first two bytes being AHI followed by ALO. This is followed by one or more data bytes. In the case of block writing it is advisable to set the starting address on the beginning of the 64-byte boundary, for example 01C0h or 0080h, but this is not mandatory. When a 64-byte boundary is crossed in the EEPROM, the I2C clock is stretched while the device performs an EEPROM write sequence. If the end of available EEPROM Document Number: 38-12036 Rev. *E Acronyms Table 3 lists the acronyms that are used in this document. Table 3. Acronyms Acronym Description AC alternating current DC direct current EEPROM electrically erasable programmable read-only memory (E2) GPIO general purpose I/O I/O input/output MSb most-significant bit POR power on reset PWM pulse width modulator Units of Measure A units of measure table is located in the Electrical Specifications section. Table 17 on page 16 lists all the abbreviations used in Section 4. Numeric Naming Hexidecimal numbers are represented with all letters in uppercase with an appended lowercase ‘h’ (for example, ‘14h’ or ‘3Ah’). Hexidecimal 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. Page 4 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Pinouts The CY8C95xxA device is available in a variety of packages, which are listed and illustrated in the following tables. 28-Pin Part Pinout Table 4. 28-Pin Part Pinout (SSOP) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 GPort0_Bit0_PWM3 GPort0_Bit1_PWM1 GPort0_Bit2_PWM3 GPort0_Bit3_PWM1 GPort0_Bit4_PWM3 GPort0_Bit5_PWM1 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 VSS I2C Serial Clock (SCL) I2C Serial Data (SDA) GPort2_Bit3_PWM3/A1 A0 VSS GPort2_Bit2_PWM0/WD INT GPort2_Bit1_PWM0/A2 GPort2_Bit0_PWM2/A3 Port 0, Bit 0, PWM 3. Port 0, Bit 1, PWM 1. Port 0, Bit 2, PWM 3. Port 0, Bit 3, PWM 1. Port 0, Bit 4, PWM 3. Port 0, Bit 5, PWM 1. Port 0, Bit 6, PWM 3. Port 0, Bit 7, PWM 1. Ground connection. I2C Clock. I2C Data. Port 2, Bit 3, PWM 3, Address 1. Address 0. Ground connection. Port 2, Bit 2, PWM 0, E2 Write Disable. 19 XRES 20 21 22 23 24 25 26 27 28 GPort1_Bit7_PWM0/A4 GPort1_Bit6_PWM2/A5 GPort1_Bit5_PWM0/A6 GPort1_Bit4_PWM2 GPort1_Bit3_PWM0 GPort1_Bit2_PWM2 GPort1_Bit1_PWM0 GPort1_Bit0_PWM2 Vdd Active high external reset with internal pull down. Port 1, Bit 7, PWM 0, Address 4. Port 1, Bit 6, PWM 2, Address 5. Port 1, Bit 5, PWM 0, Address 6. Port 1, Bit 4, PWM 2. Port 1, Bit 3, PWM 0. Port 1, Bit 2, PWM 2. Port 1, Bit 1, PWM 0. Port 1, Bit 0, PWM 2. Supply voltage. Pin Name Description Figure 2. CY8C9520A 28-Pin Device GPort0_Bit0_PWM3 GPort0_Bit1_PWM1 GPort0_Bit2_PWM3 GPort0_Bit3_PWM1 GPort0_Bit4_PWM3 GPort0_Bit5_PWM1 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 Vss I2C Serial Clock (SCL) I2C Serial Data (SDA) GPort2_Bit3_PWM3/A1 A0 Vss 1 2 3 4 5 6 7 8 9 10 11 12 13 14 SSOP 28 27 26 25 24 23 22 21 20 19 18 17 16 15 Vdd GPort1_Bit0_PWM2 GPort1_Bit1_PWM0 GPort1_Bit2_PWM2 GPort1_Bit3_PWM0 GPort1_Bit4_PWM2 GPort1_Bit5_PWM0/A6 GPort1_Bit6_PWM2/A5 GPort1_Bit7_PWM0/A4 XRES GPort2_Bit0_PWM2/A3 GPort2_Bit1_PWM0/A2 INT GPort2_Bit2_PWM0/WD Port 2, Bit 1, PWM 0, Address 2. Port 2, Bit 0, PWM 2, Address 3. Document Number: 38-12036 Rev. *E Page 5 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A 48-Pin Part Pinout Table 5. 48-Pin Part Pinout (SSOP) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 GPort0_Bit0_PWM7 GPort0_Bit1_PWM5 GPort0_Bit2_PWM3 GPort0_Bit3_PWM1 GPort0_Bit4_PWM7 GPort0_Bit5_PWM5 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 GPort3_Bit0_PWM7 GPort3_Bit1_PWM5 GPort3_Bit2_PWM3 GPort3_Bit3_PWM1 VSS GPort3_Bit4_PWM7 GPort3_Bit5_PWM5 GPort3_Bit6_PWM3 GPort3_Bit7_PWM1 GPort5_Bit2_PWM3 GPort5_Bit3_PWM1 I2C Serial Clock (SCL) I2C Serial Data (SDA) GPort2_Bit3_PWM3/A1 A0 VSS GPort2_Bit2_PWM0/WD INT GPort2_Bit1_PWM4/A2 GPort2_Bit0_PWM6/A3 GPort5_Bit1_PWM0 GPort5_Bit0_PWM2 GPort4_Bit7_PWM0 GPort4_Bit6_PWM2 GPort4_Bit5_PWM4 GPort4_Bit4_PWM6 XRES 36 37 38 39 40 41 42 43 44 45 46 47 48 GPort4_Bit3_PWM0 GPort4_Bit2_PWM2 GPort4_Bit1_PWM4 GPort4_Bit0_PWM6 GPort1_Bit7_PWM0/A4 GPort1_Bit6_PWM2/A5 GPort1_Bit5_PWM4/A6 GPort1_Bit4_PWM6 GPort1_Bit3_PWM0 GPort1_Bit2_PWM2 GPort1_Bit1_PWM4 GPort1_Bit0_PWM6 Vdd Pin Name Description Port 0, Bit 0, PWM 7. Port 0, Bit 1, PWM 5. Port 0, Bit 2, PWM 3. Port 0, Bit 3, PWM 1. Port 0, Bit 4, PWM 7. Port 0, Bit 5, PWM 5. Port 0, Bit 6, PWM 3. Port 0, Bit 7, PWM 1. Port 3, Bit 0, PWM 7. Port 3, Bit 1, PWM 5. Port 3, Bit 2, PWM 3. Port 3, Bit 3, PWM 1. Ground connection. Port 3, Bit 4, PWM 7. Port 3, Bit 5, PWM 5. Port 3, Bit 6, PWM 3. Port 3, Bit 7, PWM 1. Port 5, Bit 2, PWM 3. Port 5, Bit 3, PWM 1. I2C Clock. I2C Data. Port 2, Bit 3, PWM 3, Address 1. Address 0. Ground connection. Port 2, Bit 2, PWM 0, E2 Write Disable. Figure 3. CY8C9540A 48-Pin Device GPort0_Bit0_PWM7 GPort0_Bit1_PWM5 GPort0_Bit2_PWM3 GPort0_Bit3_PWM1 GPort0_Bit4_PWM7 GPort0_Bit5_PWM5 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 GPort3_Bit0_PWM7 GPort3_Bit1_PWM5 GPort3_Bit2_PWM3 GPort3_Bit3_PWM1 Vss GPort3_Bit4_PWM7 GPort3_Bit5_PWM5 GPort3_Bit6_PWM3 GPort3_Bit7_PWM1 GPort5_Bit2_PWM3 GPort5_Bit3_PWM1 I2C Serial Clock (SCL) I2C Serial Data (SDA) GPort2_Bit3_PWM3/A1 A0 Vss 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 SSOP 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 Vdd GPort1_Bit0_PWM6 GPort1_Bit1_PWM4 GPort1_Bit2_PWM2 GPort1_Bit3_PWM0 GPort1_Bit4_PWM6 GPort1_Bit5_PWM4/A6 GPort1_Bit6_PWM2/A5 GPort1_Bit7_PWM0/A4 GPort4_Bit0_PWM6 GPort4_Bit1_PWM4 GPort4_Bit2_PWM2 GPort4_Bit3_PWM0 XRES GPort4_Bit4_PWM6 GPort4_Bit5_PWM4 GPort4_Bit6_PWM2 GPort4_Bit7_PWM0 GPort5_Bit0_PWM2 GPort5_Bit1_PWM0 GPort2_Bit0_PWM6/A3 GPort2_Bit1_PWM4/A2 INT GPort2_Bit2_PWM0/WD Port 2, Bit 1, PWM 4, Address 2. Port 2, Bit 0, PWM 6, Address 3. Port 5, Bit 1, PWM 0. Port 5, Bit 0, PWM 2. Port 4, Bit 7, PWM 0. Port 4, Bit 6, PWM 2. Port 4, Bit 5, PWM 4. Port 4, Bit 4, PWM 6. Active high external reset with internal pull down. Port 4, Bit 3, PWM 0. Port 4, Bit 2, PWM 2. Port 4, Bit 1, PWM 4. Port 4, Bit 0, PWM 6. Port 1, Bit 7, PWM 0, Address 4. Port 1, Bit 6, PWM 2, Address 5. Port 1, Bit 5, PWM 4, Address 6. Port 1, Bit 4, PWM 6. Port 1, Bit 3, PWM 0. Port 1, Bit 2, PWM 2. Port 1, Bit 1, PWM 4. Port 1, Bit 0, PWM 6. Supply voltage. Document Number: 38-12036 Rev. *E Page 6 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A 100-Pin Part Pinout Table 6. 100-Pin Part Pinout (TQFP) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 Name DNU DNU GPort0_Bit3_PWM1 GPort0_Bit4_PWM7 GPort0_Bit5_PWM5 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 GPort3_Bit0_PWM7 GPort3_Bit1_PWM5 GPort3_Bit2_PWM3 GPort3_Bit3_PWM1 DNU DNU DNU VSS GPort3_Bit4_PWM15 GPort3_Bit5_PWM13 GPort3_Bit6_PWM11 GPort3_Bit7_PWM9 GPort5_Bit7_PWM15 GPort5_Bit6_PWM13 GPort5_Bit2_PWM11 GPort5_Bit3_PWM9 I2C Serial Clock (SCL) DNU DNU DNU I2C Serial Data (SDA) GPort2_Bit3_PWM11/A1 A0 DNU Vdd DNU VSS DNU GPort7_Bit7_PWM15 GPort7_Bit6_PWM14 GPort7_Bit5_PWM13 GPort7_Bit4_PWM12 GPort7_Bit3_PWM11 GPort7_Bit2_PWM10 GPort7_Bit1_PWM9 GPort7_Bit0_PWM8 GPort2_Bit2_PWM8/WD INT GPort2_Bit1_PWM12/A2 GPort2_Bit0_PWM14/A3 DNU DNU DNU Description DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. Port 0, Bit 3, PWM 1. Port 0, Bit 4, PWM 7. Port 0, Bit 5, PWM 5. Port 0, Bit 6, PWM 3. Port 0, Bit 7, PWM 1. Port 3, Bit 0, PWM 7. Port 3, Bit 1, PWM 5. Port 3, Bit 2, PWM 3. Port 3, Bit 3, PWM 1. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. Ground connection. Port 3, Bit 4, PWM 15. Port 3, Bit 5, PWM 13. Port 3, Bit 6, PWM 11. Port 3, Bit 7, PWM 9. Port 5, Bit 7, PWM 15. Port 5, Bit 6, PWM 13. Port 5, Bit 2, PWM 11. Port 5, Bit 3, PWM 9. I2C Clock. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. I2C Data. Port 2, Bit 3, PWM 11, Address 1. Address 0. DNU = Do Not Use; leave floating. Supply voltage. DNU = Do Not Use; leave floating. Ground connection. DNU = Do Not Use; leave floating. Port 7, Bit 7, PWM 15. Port 7, Bit 6, PWM 14. Port 7, Bit 5, PWM 13. Port 7, Bit 4, PWM 12. Port 7, Bit 3, PWM 11. Port 7, Bit 2, PWM 10. Port 7, Bit 1, PWM 9. Port 7, Bit 0, PWM 8. Port 2, Bit 2, PWM 8, E2 Write Disable. Port 2, Bit 7, PWM 0, Address 4. Port 2, Bit 6, PWM 2, Address 5. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. Document Number: 38-12036 Rev. *E Pin No. 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 Name Description DNU GPort5_Bit1_PWM8 GPort5_Bit0_PWM10 GPort5_Bit4_PWM12 GPort5_Bit5_PWM14 GPort4_Bit7_PWM8 GPort4_Bit6_PWM10 GPort4_Bit5_PWM12 GPort4_Bit4_PWM14 DNU DNU XRES GPort4_Bit3_PWM0 GPort4_Bit2_PWM2 VSS GPort4_Bit1_PWM4 GPort4_Bit0_PWM6 GPort1_Bit7_PWM0/A4 GPort1_Bit6_PWM2/A5 GPort1_Bit5_PWM4/A6 DNU GPort1_Bit4_PWM6 DNU GPort1_Bit3_PWM0 DNU DNU GPort1_Bit2_PWM2 DNU GPort1_Bit1_PWM4 DNU GPort1_Bit0_PWM6 Vdd Vdd VSS VSS GPort6_Bit0_PWM0 GPort6_Bit1_PWM1 GPort6_Bit2_PWM2 GPort6_Bit3_PWM3 GPort6_Bit4_PWM4 GPort6_Bit5_PWM5 GPort6_Bit6_PWM6 GPort6_Bit7_PWM7 DNU GPort0_Bit0_PWM7 DNU GPort0_Bit1_PWM5 DNU GPort0_Bit2_PWM3 DNU DNU = Do Not Use; leave floating. Port 5, Bit 1, PWM 8. Port 5, Bit 0, PWM 10. Port 5, Bit 4, PWM 12. Port 5, Bit 5, PWM 14. Port 4, Bit 7, PWM 8. Port 4, Bit 6, PWM 10. Port 4, Bit 5, PWM 12. Port 4, Bit 4, PWM 14. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. Active high external reset with internal pull down. Port 4, Bit 3, PWM 0. Port 4, Bit 2, PWM 2. Ground connection. Port 4, Bit 1, PWM 4. Port 4, Bit 0, PWM 6. Port 1, Bit 7, PWM 0, Address 4. Port 1, Bit 6, PWM 2, Address 5. Port 1, Bit 5, PWM 4, Address 6. DNU = Do Not Use; leave floating. Port 1, Bit 4, PWM 6. DNU = Do Not Use; leave floating. Port 1, Bit 3, PWM 0. DNU = Do Not Use; leave floating. DNU = Do Not Use; leave floating. Port 1, Bit 2, PWM 2. DNU = Do Not Use; leave floating. Port 1, Bit 1, PWM 4. DNU = Do Not Use; leave floating. Port 1, Bit 0, PWM 6. Supply voltage. Supply voltage. Ground connection. Ground connection. Port 6, Bit 0, PWM 0. Port 6, Bit 1, PWM 1. Port 6, Bit 2, PWM 2. Port 6, Bit 3, PWM 3. Port 6, Bit 4, PWM 4. Port 6, Bit 5, PWM 5. Port 6, Bit 6, PWM 6. Port 6, Bit 7, PWM 7. DNU = Do Not Use; leave floating. Port 0, Bit 0, PWM 7. DNU = Do Not Use; leave floating. Port 0, Bit 1, PWM 5. DNU = Do Not Use; leave floating. Port 0, Bit 2, PWM 3. DNU = Do Not Use; leave floating. Page 7 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Vdd Vdd GPort1_Bit0_PWM6 DNU GPort1_Bit1_PWM4 DNU GPort1_Bit2_PWM2 DNU 87 86 85 84 83 82 81 80 79 78 77 76 90 89 88 98 97 96 95 94 93 92 91 GPort6_Bit7_PWM7 GPort6_Bit6_PWM6 GPort6_Bit5_PWM5 GPort6_Bit4_PWM4 GPort6_Bit3_PWM3 GPort6_Bit2_PWM2 GPort6_Bit1_PWM1 GPort6_Bit0_PWM0 Vss Vss 75 74 TQFP 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 DNU GPort1_Bit3_PWM0 DNU GPort1_Bit4_PWM6 DNU GPort1_Bit5_PWM4/A6 GPort1_Bit6_PWM2/A5 GPort1_Bit7_PWM0/A4 GPort4_Bit0_PWM6 GPort4_Bit1_PWM4 Vss GPort4_Bit2_PWM2 GPort4_Bit3_PWM0 XRES DNU DNU GPort4_Bit4_PWM14 GPort4_Bit5_PWM12 GPort4_Bit6_PWM10 GPort4_Bit7_PWM8 GPort5_Bit5_PWM14 GPort5_Bit4_PWM12 GPort5_Bit0_PWM10 GPort5_Bit1_PWM8 DNU DNU DNU 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 GPort7_Bit7_PWM15 GPort7_Bit6_PWM14 GPort7_Bit5_PWM13 GPort7_Bit4_PWM12 GPort7_Bit3_PWM11 GPort7_Bit2_PWM10 GPort7_Bit1_PWM9 GPort7_Bit0_PWM8 GPort2_Bit2_PWM8/WD INT GPort2_Bit1_PWM12/A2 GPort2_Bit0_PWM14/A3 DNU 54 53 52 51 26 27 28 29 30 31 32 33 34 35 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 DNU DNU I2C Serial Data (SDA) GPort2_Bit3_PWM11/A1 A0 DNU Vdd DNU Vss DNU DNUa DNU GPort0_Bit3_PWM1 GPort0_Bit4_PWM7 GPort0_Bit5_PWM5 GPort0_Bit6_PWM3 GPort0_Bit7_PWM1 GPort3_Bit0_PWM7 GPort3_Bit1_PWM5 GPort3_Bit2_PWM3 GPort3_Bit3_PWM1 DNU DNU DNU Vss GPort3_Bit4_PWM15 GPort3_Bit5_PWM13 GPort3_Bit6_PWM11 GPort3_Bit7_PWM9 GPort5_Bit7_PWM15 GPort5_Bit6_PWM13 GPort5_Bit2_PWM11 GPort5_Bit3_PWM9 I2C Serial Clock (SCL) DNU 100 99 DNU GPort0_Bit2_PWM3 DNU GPort0_Bit1_PWM5 DNU GPort0_Bit0_PWM7 DNU Figure 4. CY8C9560A 100-Pin Device[2] Note 2. DNU = Do Not Use; leave floating. Document Number: 38-12036 Rev. *E Page 8 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Pin Descriptions Working with PWMs Extendable Soft Addressing 2 The A0 line defines the corresponding bit of the I C address. This pin must be pulled up or down. If A0 is a strong pull up or a strong pull down (wired through 330 or less resistor to Vdd or Vss), then that is the only address line being specified and the A1-A6 lines are used as GPIO. If A0 is a weak pull up or a weak pull down (connected to Vdd or Vss through 75K- 200K ohm resistor), then A0 is not the only externally defined address bit. There is a pin assigned to be A1 if it is needed. This pin can be pulled up or pulled down strong or weak with a resistor. As with A0, the type of pull determines whether the address bit is the last externally defined address bit. Differently from A0, A1 is not dedicated as an address pin. It is only used if A0 is not the only address bit externally defined. There are also predefined pins for A2, A3, A4, A5, and A6 that is only used for addressing if needed. The last address bit in the chain is pulled strong. That way, only the number of pins needed to assign the address desired for the part are allocated as address pins, any pins not used for address bits can be used as GPIO pins. The Table 2 on page 4 defines the resulting device I2C address. There are four independent PWMs in the CY8C9520A, eight in the CY8C9540A and sixteen in the CY8C9560A. Each I/O pin can be configured as a PWM output by writing ‘1’ to the corresponding bit of the Select PWM register (see Table 8 on page 12). The next step of PWM configuration is clock source selection using the Config PWM registers. There are six available clock sources: 32 kHz (default), 24 MHz, 1.5 MHz, 93.75 kHz, 367.6 Hz or previous PWM output. (see Figure 5) Figure 5. Clock Sources 32 kHz 24 mHz 1.5 mHz 93.75 kHz Divider (1-255) 367.6 Hz 93.75 kHz Interrupt Pin (INT) The interrupt output (if enabled) is activated if one of these events occurs: ■ One of the GPIO port pins changes state and the corresponding bit in the Interrupt Mask register is set low. ■ When a PWM driven by the slowest clock source (367.6 Hz) and assigned to a pin changes state and the pin’s corresponding bit in the Interrupt Mask register is set low. The interrupt line is deactivated when the master device performs a read from the corresponding Interrupt Status register. Write Disable Pin (WD) If this feature is enabled, ‘0’ allows writes to the EEPROM and ‘1’ blocks any memory writes. This pin is checked immediately before performing any write to memory. If the EEE bit in the Enable register is not set (EEPROM disabled) or bit EERO is set (EEPROM is read-only) then WD line level is ignored. By default, 32 kHz is selected as the PWM clock. PWM Period registers are used to set the output period: t OUT = Period × t CLK Allowed values are between 1 and FFh. The PWM Pulse Width register sets the duration of the PWM output pulse. Allowed values are between zero and the (Period-1) value. The duty cycle ratio is computed using thsi equation: PulseWidth DutyCycle = -----------------------------Period Note that ‘1’ on this line blocks all commands that perform operations with EEPROM (see Table 15 on page 14). This line may be enabled/disabled by bit 1 of the Enable register (2Dh): ‘1’ enables WD function, ‘0’ disables. External Reset Pin (XRES) A full device reset is caused by pulling the XRES pin high. The XRES pin has an always-on pull down resistor, so it does not require an external pull down for operation. It can be tied directly to ground or left open. Behavior after XRES is similar to POR. When the part is held in reset, all In and Out pins are held at their default High-Z State. Document Number: 38-12036 Rev. *E Page 9 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Figure 6. Memory Reading and Writing Memory Address Slave Address R/W S A6 A5 A4 A3 A2 A1 A0 0 Start Stop R/W A High(Addr) ACK from Slave A Low(Addr) ACK from Slave A S A6 A5 A4 A3 A2 A1 A0 1 ACK from Slave A data(Addr) ACK from Slave A data(Addr+1) ACK from Master A ... N ACK from Master P No ACK from Master Reading from EEPROM Slave Address Up to the End of Address Space Memory Address R/W S A6 A5 A4 A3 A2 A1 A0 0 Start Stop A High(Addr) ACK from Slave A Low(Addr) A data 1 A data 2 A ... A P ACK from Slave ACK from Slave If current address crosses 64-byte block boundary, then device performs real writing to EEPROM Writing to EEPROM Figure 7. Port Reading and Writing in Multi-Port Device Slave Address Register Address = 1 Reading from GPort 2 At this moment, device performs reading from GPort 1 R/W R/W S A6 A5 A4 A3 A2 A1 A0 0 Start A 0 0 0 0 0 0 0 ACK from Slave 1 A S A6 A5 A4 A3 A2 A1 A0 1 ACK from Slave Stop A data from GPort1 A data from GPort 2 A ... N P No ACK from Master ACK from Master Reading from GPort 1 Slave Address Register Address = 09h Output to GPort 2 Output to GPort 3 At this moment, device performs output to GPort 1 Stop R/W S A6 A5 A4 A3 A2 A1 A0 0 Start A 0 0 ACK from Slave 0 0 1 0 0 1 A data from GPort1 A data from GPort 2 A data from GPort 3 ACK from Slave ACK from Slave A ... P ACK from Slave Writing from GPort 1 Document Number: 38-12036 Rev. *E Page 10 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Register Mapping Table Table 7. The Device Register Address Map (continued) The register address is auto-incrementing. If the master device writes or reads data to or from one register and then continues data transfer in the same I2C transaction, sequential bytes are written or read to or from the following registers. For example, if the first byte is sent to the Output Port 1 register, then the next bytes are written to Output Port 2, Output Port 3, Output Port 4 etc. The first byte of each write transaction is treated as the register address. Address Register Default Register Value 1Ah Select PWM for Port Output 00h 1Bh Inversion 00h 1Ch Pin Direction - Input/Output 00h 1Dh Drive Mode - Pull Up FFh 1Eh Drive Mode - Pull Down 00h 1Fh Drive Mode - Open Drain High 00h 20h 00h To read a specific register address, the master device must write the register address byte, then perform a start and read transaction. Drive Mode - Open Drain Low 21h Drive Mode - Strong 00h 22h Drive Mode - Slow Strong 00h See Figure 7 on page 10. 23h Drive Mode - High-Z 00h The device’s register mapping is listed in Table 7. 24h Reserved None 25h Reserved None To read data from a seires of registers, the master device must write the starting register address byte then perform a start and series of read transactions. If no address was sent, reads start from address 0. Table 7. The Device Register Address Map Address 00h Register Input Port 0 26h Reserved None Default Register Value 27h Reserved None None 28h PWM Select 00h Config PWM 00h 01h Input Port 1 None 29h 02h Input Port 2 None 2Ah Period PWM FFh Pulse Width PWM 80h 03h Input Port 3 None 2Bh 04h Input Port 4 None 2Ch Programmable Divider FFh Enable WDE, EEE, EERO 00h 05h Input Port 5 None 2Dh 06h Input Port 6 None 2Eh Device ID/Status 20h/40h/60h Watchdog 00h Command 00h 07h Input Port 7 None 2Fh 08h Output Port 0 FFh 30h 09h Output Port 1 FFh 0Ah Output Port 2 FFh 0Bh Output Port 3 FFh 0Ch Output Port 4 FFh 0Dh Output Port 5 FFh 0Eh Output Port 6 FFh 0Fh Output Port 7 FFh 10h Interrupt Status Port 0 00h 11h Interrupt Status Port 1 00h These registers represent actual logical levels on the pins and are used for I/O port reading operations. They are read only. The Inversion registers changes the state of reads to these ports. 12h Interrupt Status Port 2 00h Output Port Registers (08h - 0Fh) 13h Interrupt Status Port 3 00h 14h Interrupt Status Port 4 00h 15h Interrupt Status Port 5 00h 16h Interrupt Status Port 6 00h These registers are used for writing data to GPIO ports. By default, all ports are in the pull up mode allowing quasi-bidirectional I/O. To allow input operations without reconfiguration, these registers have to store ’1’s. 17h Interrupt Status Port 7 00h Output register data also affects pin states when PWMs are enabled. See Table 8 on page 12 for details. 18h Port Select 00h See Figure 7 on page 10 illustrates port read/write procedures. 19h Interrupt Mask FFh The Inversion registers have no effect on these ports. Document Number: 38-12036 Rev. *E Register Descriptions The registers for the CY8C95xx are described in the sections that follow. Note that the PWM registers are located at addresses 28h to 2Bh. Input Port Registers (00h - 07h) Page 11 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Int. Status Port Registers (10h - 17h) Each ’1’ bit in these registers signals that there was a change in the corresponding input line since the last read of that Interrupt Status register. Each Interrupt (Int.) Status register is cleared only after a read of that register. The Input registers' logic is presented in Table 9. These registers have no effect on outputs or PWMs. Table 9. Inversion Register Logic If a PWM is assigned to a pin, then all state changes of the PWM sets the corresponding bit in the Interrupt Status register. If the pin's interrupt mask is cleared and the PWM is set to the slowest possible rate allowed (driven by the programmable clock source with divide register 2Dh set to FFh), then the INT line also drives on the PWM state change. Pin State Invert Input 0 0 0 1 0 1 0 1 1 1 1 0 Port Select Register (18h) Port Direction Register (1Ch) This register configures the GPort. Write a value of 0-7 to this register to select the port to program with registers 19h-23h. Each bit in a port is configurable as either an input or an output. To perform this configuration, the Port Direction register (1Ch) is used for the GPort selected by the Port Select register (18h). If a bit in this register is set (written with '1'), the corresponding port pin is enabled as an input. If a bit in this register is cleared (written with '0'), the corresponding port pin is enabled as an output. Interrupt Mask Port Register (19h) The Interrupt Mask register enables or disables activation of the INT line when GPIO input levels are changed. Each ’1’ in the Interrupt Mask register masks (disables) interrupts generated from the corresponding input line of the GPort selected by the Port Select register (18h). Select PWM Register (1Ah) This register allows each port to act as a PWM output. By default, all ports are configured as GPIO lines. Each ’1’ in this register connects the corresponding pin of the GPort selected by the Port Select register (18h) to the PWM output. Output register data also affects the pin state when a PWM is enabled. See Table 8. Note that a pin used as PWM output must be configured to the appropriate drive mode. See Table 10 on page 12 for more information. Table 8 describes the logic of the Output and Select PWM registers. Table 8. Output and Select PWM Registers Logic Drive Mode Registers (1Dh-23h) Each port's data pins can be set separately to one of seven available modes: pull up or down, open drain high/low, strong drive fast/slow, or high-impedance input. To perform this configuration, the seven drive mode registers are used for the GPort selected by the Port Select register (18h). Each ’1’ written to this register changes the corresponding line drive mode. Registers 1Dh through 23h have last register priority meaning that the bit set to high in which the last register was written overrides those that came before. Reading these registers reflects the actual setting, not what was originally written. Table 10. Drive Mode Register Settings Reg. Pin State 1Dh Resistive Pull Up Description Resistive High, Strong Low (default) Output Select PWM Pin State 1Eh Resistive Pull Down Strong High, Resistive Low 0 0 0 1Fh Open Drain High 1 0 1 20h Open Drain Low Slow Strong Low, High Z High 0 1 0 21h Strong Drive 1 1 Current PWM Strong High, Strong Low, Fast Output Mode 22h Slow Strong Drive Strong High, Strong Low, Slow Output Mode 23h High Impedance High Z Inversion Register (1Bh) This register can invert the logic of the input ports. Each ’1’ written to this register inverts the logic of the corresponding bit in the Input register of the GPort selected by the Port Select register (18h). Slow Strong High, High Z Low PWM Select Register (28h) This register is configures the PWM. Write a value of 00h-0Fh to this register to select the PWM to program with registers 29h-2Bh. Document Number: 38-12036 Rev. *E Page 12 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Config (29h) Divider Register (2Ch) This register selects the clock source for the PWM selected by the PWM Select register (28h) and interrupt logic. This register sets the frequency on the output of the programmable divider: There are six available clock sources: 32 kHz (default), 24 MHz, 1.5 MHz, 93.75 kHz, 367.6 Hz, or previous PWM output. The 367.6 Hz clock is user programmable. It divides the 93.75 kHz clock source by the divisor stored in the Divider register (2Ch). The default divide ratio is 255. (see Table 11 for details). By default, all PWMs are clocked from 32 kHz. Frequency = Table 11. PWM Clock Sources Config PWM PWM Clock Source xxxxx000b 32 kHz (default) xxxxx001b 24 MHz xxxxx010b 1.5 MHz xxxxx011b 93.75 kHz xxxxx100b 367.6 Hz (programmable) xxxxx101b Previous PWM 93.75 kHz . Divider Allowed values are between 1 and 255. Enable Register (2Dh) The WDE bit configures the write disable pin to operate either as a GPIO or as WD. It also enables/disables EEPROM operations (EEE bit) or makes the EEPROM read-only (EERO bit). Bit assignments are shown in Table 13 on page 13. Table 13. Enable Register Bit Each PWM can generate an interrupt at the rising or falling edge of the output pulse. There is a limitation on the clock source for a PWM to generate an interrupt. Only the slowest speed source (programmed to 367.6 Hz) with the divider equal to 255 allows interrupt generation. Consequently, to create a PWM interrupt, it is necessary to choose the programmable divider output as the clock source (write xxxxx100b to Config register (29h)), write 255 to the Divide register (2Ch), and select PWM for pin output (1Ah). Interrupt status is reflected in the Interrupt Status registers (10h-17h) and can cause INT line activation if enabled by the corresponding mask bit in the Interrupt Mask register: 7 6 5 4 3 2 1 0 Function Reserved EERO EEE WDE Default Reserved 0 0 0 Each ’1’ enables the corresponding feature, ’0’ disables. Writes to this register differ from other registers. The write sequence to modify the Enable register is as follows: 1. Send device I2C address with bit 0. 2. Send register address 2Dh. 3. Send unlock key - the sequence of three bytes: 43h, 4Dh, 53h; ('C', 'M', 'S' in ASCII bytes). 4. Send new Enable register value. Period Register (2Ah) This write sequence secures the register from accidental changes. The register can be read without the use of the unlock key. Table 12. Period Register By default, EERO and EEPROM (EEE bit) are disabled and WD line (WDE bit) is set to GPIO (WD disabled). Config PWM PWM Interrupt on xxxx0xxxb Falling pulse edge (default) xxxx1xxxb Rising pulse edge When performing a burst write operation that crosses this register, the data written to this register is ignored and the address increments to 2Eh. Device ID/Status Register (2Eh) This register sets the period of the PWM counter. Allowed values are between 1 and FFh. The effective output waveform period of the PWM is: tOUT = Period ⋅ tCLK Pulse Width Register (2Bh) This register sets the pulse width of the PWM output. Allowed values are between zero and the (Period - 1) value. The duty cycle ratio can be computed using the following equation: This register stores device identifiers (2xh/4xh/6xh) and reflects which settings were loaded during startup, either factory defaults (FD) or user defaults (UD). By default during startup, the device attempts to load the user default block. If it is corrupted then factory defaults are loaded and the low nibble of this register is set high to inform which set is active. The high nibble is always equal to 2 for CY8C9520A, 4 for CY8C9540A, and 6 for CY8C9560A. This register is read-only. Table 14. Device ID Status Register Bit DutyCycle = PulseWidth . Period Document Number: 38-12036 Rev. *E 7 6 5 4 Function Device Family (2, 4,or 6) 3 2 Reserved 1 0 FD/UD Page 13 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Watchdog Register (2Fh) Write E2 POR Defaults Cmd (03h) This register controls the internal Watchdog timer. This timer can trigger a device reset if the device is not responding to I2C requests due to misconfiguration. Device operation is not affected when the Watchdog register = 0. If the I2C master writes any non zero value to the Watchdog register, the countdown mechanism is activated and each second the register is decremented. Upon transition from 1 to 0, the device is rebooted, which restores user defaults. After reboot, the Watchdog register value is reset to zero. Any I2C transaction (addressing the Expander) resets the Watchdog register to the previously stored value. Any device reboot (caused by a POR or Watchdog) sets the Watchdog register to zero (turns off the Watchdog feature). The Watchdog timer can be disabled by writing zero to the Watchdog register (2Fh) or by using the Reconfigure Device Cmd (07h). This command sends new power up defaults to the CY8C95xx without changing current settings unless the 07h command is issued afterwards. This command is followed by 147 data bytes according to Table 16. The CRC is calculated as the XOR of the 146 data bytes (00h-91h). If the CRC check fails or an incomplete block is sent, then the slave responds with a NAK and the data does not get saved to EEPROM. Note The Watchdog timer is not intended to track precise time intervals. The timer's frequency can vary in range between -50% on up to +100%. This variation must be taken into account when selecting the appropriate value for the Watchdog register. To define new POR defaults the user must: ■ Write command 03h ■ Write 146 data bytes with new values of registers ■ Write 1 CRC byte calculated as XOR of previous 146 data bytes. Content of the data block is described in Table 16. Table 16. POR Defaults Data Structure Offset Value Command Register (30h) 00h – 07h Output Port 0-7 This register sends commands to the device, including current configuration as new POR defaults, restore factory defaults, define POR defaults, read POR defaults, write device configuration, read device configuration, and reconfigure device with stored POR defaults. The command set is presented in Table 15. 08h – 0Fh Interrupt mask Port 0-7 10h – 17h Select PWM Port 0-7 Note Registers are not restored in parallel. Do not assume any particular order to the restoration process. 28h Resistive pull up Drive Mode Port 0 29h Resistive pull down Drive Mode Port 0 2Ah Open drain high Drive Mode Port 0 2Bh Open drain low Drive Mode Port 0 2Ch Strong drive Drive Mode Port 0 2Dh Slow strong drive Drive Mode Port 0 2Eh High impedance Drive Mode Port 0 2Fh – 35h Drive Modes Port 1 Table 15. Available Commands Command Description 01h Store device configuration to EEPROM POR defaults 02h Restore Factory Defaults 03h Write EEPROM POR defaults 04h Read EEPROM POR defaults 05h Write device configuration 06h Read device configuration 07h Reconfigure device with stored POR defaults Commands Description Store Config to E2 POR Defaults Cmd (01h) The current ports settings (drive modes and output data) and other configuration registers are saved in the EEPROM by using the store configuration command (Cmd). These settings are automatically loaded after the next device power up or if the 07h command is issued. 18h – 1Fh Inversion Port 0-7 20h – 27h Pin Direction Port 0-7 36h – 3Ch Drive Modes Port 2 3Dh – 43h Drive Modes Port 3 44h – 4Ah Drive Modes Port 4 4Bh – 51h Drive Modes Port 5 52h – 58h Drive Modes Port 6 59h – 5Fh Drive Modes Port 7 60h Config setting PWM0 61h Period setting PWM0 62h Pulse Width setting PWM0 63h – 65h PWM1 settings … … 8Dh – 8Fh PWM15 settings Restore Factory Defaults Cmd (02h) 90h Divider This command replaces the saved user configuration with the factory default configuration. Current settings are unaffected by this command. New settings are loaded after the next device power up or if the 07h command is issued. 91h Enable 92h CRC Document Number: 38-12036 Rev. *E Page 14 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Read E2 POR Defaults Cmd (04h) Read Device Config Cmd (06h) This command reads the POR settings stored in the EEPROM. This command reads the current device configuration. It gives the user ‘flat-address-space’ access to all device settings. To read POR defaults the user must: ■ Write command 04h ■ Read 146 data bytes (see Table 16) ■ Read 1 CRC byte. Write Device Config Cmd (05h) This command sends a new device configuration to the CY8C95xx. It is followed by 146 data bytes according to Table 16. The CRC is calculated as the XOR of the 146 data bytes (00h-91h). If the CRC check fails or an incomplete block is sent, then the slave responds with a NAK and the device does not use the data. This gives the user ‘flat-address-space’ access to all device settings. To read device configuration the user must: ■ Write command 06h ■ Read 146 data bytes (see Table 16). ■ Read 1 CRC byte. Reconfigure Device Cmd (07h) This command immediately reconfigures the device with actual POR defaults from EEPROM. It has the same effect on the registers as a POR. To set the current device configuration the user must: ■ Write command 05h ■ Write 146 data bytes with new values of registers ■ Write 1 CRC byte calculated as XOR of previous 146 data bytes. If the CRC check passes, then the device uses the new settings immediately. Content of the data block is described in Table 16. Document Number: 38-12036 Rev. *E Page 15 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Electrical Specifications This section lists the DC and AC electrical specifications of the CY8C95xxA device. For the most up to date electrical specifications, confirm that you have the most recent data sheet by going to the web at http://www.cypress.com. Specifications are valid for -40°C ≤ TA ≤ 85°C and TJ ≤ 100°C, except where noted. Table 17 lists the units of measure that are used in this section. Table 17. Units of Measure Symbol °C kHz MHz μs μV μVrms Unit of Measure degree Celsius kilohertz megahertz microsecond microvolts microvolts root-mean-square Symbol mA nA ns pF V Unit of Measure milli-ampere nanoampere nanosecond picofarad volts Absolute Maximum Ratings Table 18. Absolute Maximum Ratings Symbol TSTG Description Storage temperature TBAKETEMP Bake Temperature Min -55 Typ 25 Max +100 Units °C – 125 °C – See package label 72 TBAKETIME Bake Time TA Vdd VIO Ambient temperature with power applied Supply voltage on Vdd relative to Vss DC input voltage See package label -40 -0.5 Vss - 0.5 VIOZ DC voltage applied to tri-state Vss - 0.5 – IMIO ESD LU Maximum current into any port pin Electro Static Discharge Voltage Latch up current -25 2000 – Min -40 -40 – – – Notes Higher storage temperatures reduces data retention time. Recommended storage temperature is +25°C ± 25°C. Extended duration storage temperatures above 65°C degrades reliability. Hours °C V V – – – +85 +6.0 Vdd + 0.5 Vdd + 0.5 +50 – 200 mA V mA Typ – – Max +85 +100 Units °C °C V Human Body Model ESD. Operating Temperature Table 19. Operating Temperature Symbol TA TJ Description Ambient temperature Junction temperature Document Number: 38-12036 Rev. *E Notes The temperature rise from ambient to junction is package specific. See “Thermal Impedances per Package” on page 23. The user must limit the power consumption to comply with this requirement. Page 16 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A DC Electrical Characteristics DC Chip-Level Specifications Table 20 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only. Table 20. CY8C9520A DC Chip-Level Specifications Symbol Description Vdd Supply voltage IDD Supply current Vdd 5V IDD3 Supply current Vdd 3.3V Min 3.00 – – Typ – 3.8 2.3 Max 5.25 5 3 Units V mA mA Typ – 6 3.3 Max 5.25 9 6 Units V mA mA Typ – 15 5 Max 5.25 25 9 Units V mA mA Notes Conditions are 5.0V, TA = 25°C, IOH = 0. Conditions are 3.3V, TA = 25°C, IOH = 0. Table 21. CY8C9540A DC Chip-Level Specifications Symbol Description Vdd Supply voltage IDD Supply current Vdd 5V IDD3 Supply current Vdd 3.3V Min 3.00 – – Notes Conditions are 5.0V, TA = 25°C, IOH = 0. Conditions are 3.3V, TA = 25°C, IOH = 0. Table 22. CY8C9560A DC Chip-Level Specifications Symbol Description Vdd Supply voltage IDD Supply current Vdd 5V IDD3 Supply current Vdd 3.3V Min 3.00 – – Notes Conditions are 5.0V, TA = 25°C, IOH = 0. Conditions are 3.3V, TA = 25°C, IOH = 0. DC Programming Specifications The following table lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only. Table 23. DC Programming Specifications Symbol FlashENPB FlashENT FlashDR Description Flash (EEPROM) endurance (by block) Flash endurance (total)[3] Flash data retention Min 10,000 1,800,000 10 Typ – – – Max – – – Units – – Years Notes Erase/write cycles by block. Erase/write cycles. DC I2C Specifications Table 24 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only. Table 24. DC I2C Specifications[4] Symbol VILI2C Input low level Description VIHI2C Input high level Min – – 0.7 × VDD Typ – – – Max 0.3 × VDD 0.25 × VDD – Units V V V Notes 3.0 V ≤ VDD ≤ 3.6 V 4.75 V ≤ VDD ≤ 5.25 V 3.0 V ≤ VDD ≤ 5.25 V Note 3. A maximum of 180 x 10,000 block endurance cycles is allowed. This may be balanced between operations on 180x1 blocks of 10,000 maximum cycles each, 180x2 blocks of 5,000 maximum cycles each, or 180x4 blocks of 2,500 maximum cycles each (to limit the total number of cycles to 180x10,000 and that no single block ever sees more than 10,000 cycles). 4. All GPIO meet the DC GPIO VIL and VIH specifications found in the DC GPIO Specifications sections. The I2C GPIO pins also meet the above specs. Document Number: 38-12036 Rev. *E Page 17 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A DC GPIO Specifications The following table lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only. Table 25. DC GPIO Specifications Min Typ Max Units Notes VOH Symbol High output level Description Vdd - 1.0 – – V IOH = 10 mA for any one pin, Vdd = 4.75 to 5.25V. 40 mA maximum combined IOH for GPort0; GPort2_Bit3; GPort3; GPort5_Bit2, 3, 6, 7; GPort6. 40 mA maximum combined IOH for GPort1; GPort2_Bit0, 1, 2; GPort4; GPort5_Bit0, 1, 4, 5; GPort7. 80 mA maximum combined IOH. VOL Low output level – – 0.75 V IOL = 25 mA for any one pin, Vdd = 4.75 to 5.25V. 100 mA maximum combined IOL for GPort0; GPort2_Bit3; GPort3; GPort5_Bit2, 3, 6, 7; GPort6. 100 mA maximum combined IOL for GPort1; GPort2_Bit0, 1, 2; GPort4; GPort5_Bit0, 1, 4, 5; GPort7. 200 mA maximum combined IOL. IOH High Level Source Current 10 – – mA VOH = Vdd-1.0V, see the limitations of the total current in the note for VOH IOL Low Level Sink Current 25 – – mA VOL = 0.75V, see the limitations of the total current in the note for VOL VIL Input low level – – 0.8 V Vdd = 3.0 to 5.5. VIH Input high level 2.1 – – V Vdd = 3.0 to 5.5. IIL Input leakage (absolute value) – 1 – nA Gross tested to 1 μA. CIN Capacitive load on pins as input – 3.5 10 pF Package and pin dependent. Temp = 25°C. COUT Capacitive load on pins as output – 3.5 10 pF Package and pin dependent. Temp = 25°C. Document Number: 38-12036 Rev. *E Page 18 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A AC Electrical Characteristics AC GPIO Specifications Table 26 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only or unless otherwise specified. Table 26. AC GPIO Specifications Symbol FGPIO TRiseF TFallF TRiseS TFallS Description GPIO Operating Frequency Rise time, normal strong mode, Cload = 50 pF Fall time, normal strong mode, Cload = 50 pF Rise time, slow strong mode, Cload = 50 pF Fall time, slow strong mode, Cload = 50 pF Min 0 3 2 10 10 Typ – – – 27 22 Max 12 18 18 – – Units MHz ns ns ns ns Notes Normal Strong Mode Vdd = 4.75 to 5.25V, 10% - 90% Vdd = 4.75 to 5.25V, 10% - 90% Vdd = 3 to 5.25V, 10% - 90% Vdd = 3 to 5.25V, 10% - 90% Figure 8. GPIO Timing Diagram 90% GPIO Pin Output Voltage 10% TRiseF TRiseS TFallF TFallS AC PWM Specifications Table 27 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only or unless otherwise specified. Table 27. AC PWM Specifications Symbol Description Jitter24MHzPWM 24 MHz based PWM peak-to-peak period jitter Jitter32kHzPWM F24MHzPWM F32kHzPWM F1.5MHzPWM F93.75kHzPWM 32 kHz-based PWM peak-to-peak period jitter Input Frequency of 24 MHz based PWM Input Frequency of 32 kHz based PWM Input frequency of 1.5 MHz based PWM Input Frequency of 93.75 kHz based PWM Document Number: 38-12036 Rev. *E Min – Typ 0.1 Max 1.5 Units % – 2.5 5.0 % 23.4 15 1.46 91.40 24 32 1.5 93.75 24.6 64 1.53 96.09 MHz kHz MHz kHz Notes 24 MHz, 1.5 MHz, 93.75 kHz and 367.6 Hz (programmable) sources. 32 kHz clock source. Page 19 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A AC I2C Specifications Table 28 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only or unless otherwise specified. Table 28. AC Characteristics of the I2C SDA and SCL Pins Symbol Description SCL clock frequency FSCLI2C THDSTAI2C Hold time (repeated) START condition. After this period, the first clock pulse is generated. TLOWI2C LOW period of the SCL clock HIGH period of the SCL clock THIGHI2C TSUSTAI2C Setup time for a repeated START condition THDDATI2C Data hold time TSUDATI2C Data setup time TSUSTOI2C Setup time for STOP condition Bus free time between a STOP and START TBUFI2C Condition TSPI2C Pulse width of spikes are suppressed by the input filter. Standard Mode Min Max 0 100 4.0 – Fast Mode Min Max 0 – 0.6 – Units Notes kHz μs 4.7 4.0 4.7 0 250 4.0 4.7 – – – – – – – 1.3 0.6 0.6 0 1003 0.6 1.3 – – – – – – – μs μs μs μs ns μs μs – – 0 – ns Figure 9. Definition for Timing for Fast/Standard Mode on the I2C Bus I2C_SDA TSUDATI2C THDSTAI2C TSPI2C THDDATI2CTSUSTAI2C TBUFI2C I2C_SCL THIGHI2C TLOWI2C TSUSTOI2C P Sr S START Condition S STOP Condition Repeated START Condition AC EEPROM Write Specifications Table 29 lists guaranteed maximum and minimum specifications for the voltage and temperature ranges: 4.75V to 5.25V and -40°C ≤ TA ≤ 85°C, or 3.0V to 3.6V and -40°C ≤ TA ≤ 85°C, respectively. Typical parameters apply to 5V and 3.3V at 25°C and are for design guidance only or unless otherwise specified. Table 29. AC EEPROM Write Specifications Symbol Description Min Typ Max Units Notes TEEPROMWrite_Hot EEPROM Erase + Write time – – 100 ms 0°C ≤ Tj ≤ 100°C TEEPROMWrite_Cold EEPROM Erase + Write time – – 200 ms -40°C ≤ Tj ≤ 0°C Document Number: 38-12036 Rev. *E Page 20 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Packaging Dimensions This section illustrates the packaging specifications for the CY8C95xxA device, along with the thermal impedances for each package and the solder reflow peak temperature. Important Note Emulation tools may require a larger area on the target PCB than the chip’s footprint. For a detailed description of the emulation tools’ dimensions, refer to the emulator pod drawings at http://www.cypress.com. Figure 10. 28-Pin (210-Mil) SSOP 51-85079 *D Document Number: 38-12036 Rev. *E Page 21 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Figure 11. 48-Pin (300-Mil) SSOP .020 24 1 0.395 0.420 0.292 0.299 25 DIMENSIONS IN INCHES MIN. MAX. 48 0.620 0.630 0.088 0.092 0.095 0.110 0.025 BSC SEATING PLANE 0.005 0.010 .010 GAUGE PLANE 0.004 0.008 0.0135 0.008 0.016 0°-8° 0.024 0.040 51-85061 *D Figure 12. 100-Pin (14 x 14 x 1.0 mm) TQFP 51-85048 *D Document Number: 38-12036 Rev. *E Page 22 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Thermal Impedances Table 30. Thermal Impedances per Package Typical θJA [5] 101 °C/W 69 °C/W 48 °C/W Package 28 SSOP 48 SSOP 100 TQFP Solder Reflow Peak Temperature Table 31 lists the minimum solder reflow peak temperature to achieve good solderability. Table 31. Solder Reflow Peak Temperature Package Maximum Peak Temperature Time at Maximum Peak Temperature 28 SSOP 260 °C 20 s 48 SSOP 260 °C 20 s 100 TQFP 260 °C 20 s Notes 5. TJ = TA + POWER x θJA. Document Number: 38-12036 Rev. *E Page 23 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Features and Ordering Information Table 32 lists the CY8C95xxA device’s key package features and ordering codes. A definition of the ordering number code follows. Table 32. CY8C95xxA Device Key Features and Ordering Information Package 28 Pin (210 Mil) SSOP 28 Pin (210 Mil) SSOP (Tape and Reel) 48 Pin (300 Mil) SSOP 48 Pin (300 Mil) SSOP (Tape and Reel) 100 Pin TQFP 100 Pin TQFP (Tape and Reel) Ordering Code[6] CY8C9520A-24PVXI CY8C9520A-24PVXIT CY8C9540A-24PVXI CY8C9540A-24PVXIT CY8C9560A-24AXI CY8C9560A-24AXIT EEPROM (Bytes) 3K 3K 11K 11K 27K 27K Temperature Range -40°C to +85°C -40°C to +85°C -40°C to +85°C -40°C to +85°C -40°C to +85°C -40°C to +85°C PWM Sources 4 4 8 8 16 16 Configurable I/O Pins 20 20 40 40 60 60 Ordering Code Definitions CY 8 C 9 xxx-SPxx Package Type: Thermal Rating: PX = PDIP Pb-Free C = Commercial SX = SOIC Pb-Free I = Industrial PVX = SSOP Pb-Free E = Extended LFX/LKX/LTX/LQX/LCX = QFN Pb-Free AX = TQFP Pb-Free Speed: 24 MHz Part Number Family Code Technology Code: C = CMOS Marketing Code: 8 = Cypress PSoC Company ID: CY = Cypress Note 6. The A after the existing port expander part number indicates new device firmware. Document Number: 38-12036 Rev. *E Page 24 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Acronyms Table 33 lists the acronyms that are used in this document. Table 33. Acronyms Used in this Datasheet Acronym Description AC alternating current API application programming interface CMOS CRC DC EEPROM Acronym POR PSoC® Description power on reset Programmable System-on-Chip complementary metal oxide semiconductor PWM pulse width modulator cyclic redundancy check SSOP shrink small-outline package direct current TQFP thin quad flat pack electrically erasable programmable read-only memory UART universal asynchronous reciever / transmitter GPIO general purpose I/O USB universal serial bus MSB most-significant bit WDT watchdog timer PCB printed circuit board XRES external reset Reference Documents Communication – I2C Port Expander with Flash Storage – AN2304 (001-27119) Document Conventions Units of Measure Table 34 lists the units of measures. Table 34. Units of Measure Symbol °C Unit of Measure degree Celsius Symbol Unit of Measure nA nanoampere pF picofarad µs microsecond Hz Hertz ms millisecond kHz kilohertz ns nanosecond MHz megahertz V volts W watt kΩ kilohm Ω ohm µA microampere mA milliampere mm % millimeter percent Numeric Conventions 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’ or ‘b’ are decimals. Document Number: 38-12036 Rev. *E Page 25 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Glossary active high 1. A logic signal having its asserted state as the logic 1 state. 2. A logic signal having the logic 1 state as the higher voltage of the two states. analog blocks The basic programmable opamp circuits. These are SC (switched capacitor) and CT (continuous time) blocks. These blocks can be interconnected to provide ADCs, DACs, multi-pole filters, gain stages, and much more. analog-to-digital (ADC) A device that changes an analog signal to a digital signal of corresponding magnitude. Typically, an ADC converts a voltage to a digital number. The digital-to-analog (DAC) converter performs the reverse operation. Application programming interface (API) A series of software routines that comprise an interface between a computer application and lower level services and functions (for example, user modules and libraries). APIs serve as building blocks for programmers that create software applications. asynchronous A signal whose data is acknowledged or acted upon immediately, irrespective of any clock signal. bandgap reference A stable voltage reference design that matches the positive temperature coefficient of VT with the negative temperature coefficient of VBE, to produce a zero temperature coefficient (ideally) reference. bandwidth 1. The frequency range of a message or information processing system measured in hertz. 2. The width of the spectral region over which an amplifier (or absorber) has substantial gain (or loss); it is sometimes represented more specifically as, for example, full width at half maximum. bias 1. A systematic deviation of a value from a reference value. 2. The amount by which the average of a set of values departs from a reference value. 3. The electrical, mechanical, magnetic, or other force (field) applied to a device to establish a reference level to operate the device. block 1. A functional unit that performs a single function, such as an oscillator. 2. A functional unit that may be configured to perform one of several functions, such as a digital PSoC block or an analog PSoC block. buffer 1. A storage area for data that is used to compensate for a speed difference, when transferring data from one device to another. Usually refers to an area reserved for IO operations, into which data is read, or from which data is written. 2. A portion of memory set aside to store data, often before it is sent to an external device or as it is received from an external device. 3. An amplifier used to lower the output impedance of a system. bus 1. A named connection of nets. Bundling nets together in a bus makes it easier to route nets with similar routing patterns. 2. A set of signals performing a common function and carrying similar data. Typically represented using vector notation; for example, address[7:0]. 3. One or more conductors that serve as a common connection for a group of related devices. clock The device that generates a periodic signal with a fixed frequency and duty cycle. A clock is sometimes used to synchronize different logic blocks. comparator An electronic circuit that produces an output voltage or current whenever two input levels simultaneously satisfy predetermined amplitude requirements. Document Number: 38-12036 Rev. *E Page 26 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Glossary (continued) compiler A program that translates a high level language, such as C, into machine language. configuration space In PSoC devices, the register space accessed when the XIO bit, in the CPU_F register, is set to ‘1’. crystal oscillator An oscillator in which the frequency is controlled by a piezoelectric crystal. Typically a piezoelectric crystal is less sensitive to ambient temperature than other circuit components. cyclic redundancy A calculation used to detect errors in data communications, typically performed using a linear check (CRC) feedback shift register. Similar calculations may be used for a variety of other purposes such as data compression. data bus A bi-directional set of signals used by a computer to convey information from a memory location to the central processing unit and vice versa. More generally, a set of signals used to convey data between digital functions. debugger A hardware and software system that allows you to analyze the operation of the system under development. A debugger usually allows the developer to step through the firmware one step at a time, set break points, and analyze memory. dead band A period of time when neither of two or more signals are in their active state or in transition. digital blocks The 8-bit logic blocks that can act as a counter, timer, serial receiver, serial transmitter, CRC generator, pseudo-random number generator, or SPI. digital-to-analog (DAC) A device that changes a digital signal to an analog signal of corresponding magnitude. The analogto-digital (ADC) converter performs the reverse operation. duty cycle The relationship of a clock period high time to its low time, expressed as a percent. emulator Duplicates (provides an emulation of) the functions of one system with a different system, so that the second system appears to behave like the first system. External Reset (XRES) An active high signal that is driven into the PSoC device. It causes all operation of the CPU and blocks to stop and return to a pre-defined state. Flash An electrically programmable and erasable, non-volatile technology that provides you the programmability and data storage of EPROMs, plus in-system erasability. Non-volatile means that the data is retained when power is OFF. Flash block The smallest amount of Flash ROM space that may be programmed at one time and the smallest amount of Flash space that may be protected. A Flash block holds 64 bytes. frequency The number of cycles or events per unit of time, for a periodic function. gain The ratio of output current, voltage, or power to input current, voltage, or power, respectively. Gain is usually expressed in dB. I2C A two-wire serial computer bus by Philips Semiconductors (now NXP Semiconductors). I2C is an Inter-Integrated Circuit. It is used to connect low-speed peripherals in an embedded system. The original system was created in the early 1980s as a battery control interface, but it was later used as a simple internal bus system for building control electronics. I2C uses only two bi-directional pins, clock and data, both running at +5V and pulled high with resistors. The bus operates at 100 kbits/second in standard mode and 400 kbits/second in fast mode. Document Number: 38-12036 Rev. *E Page 27 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Glossary (continued) ICE The in-circuit emulator that allows you to test the project in a hardware environment, while viewing the debugging device activity in a software environment (PSoC Designer). input/output (I/O) A device that introduces data into or extracts data from a system. interrupt A suspension of a process, such as the execution of a computer program, caused by an event external to that process, and performed in such a way that the process can be resumed. interrupt service routine (ISR) A block of code that normal code execution is diverted to when the M8C receives a hardware interrupt. Many interrupt sources may each exist with its own priority and individual ISR code block. Each ISR code block ends with the RETI instruction, returning the device to the point in the program where it left normal program execution. jitter 1. A misplacement of the timing of a transition from its ideal position. A typical form of corruption that occurs on serial data streams. 2. The abrupt and unwanted variations of one or more signal characteristics, such as the interval between successive pulses, the amplitude of successive cycles, or the frequency or phase of successive cycles. low-voltage detect A circuit that senses Vdd and provides an interrupt to the system when Vdd falls below a (LVD) selected threshold. M8C An 8-bit Harvard-architecture microprocessor. The microprocessor coordinates all activity inside a PSoC by interfacing to the Flash, SRAM, and register space. master device A device that controls the timing for data exchanges between two devices. Or when devices are cascaded in width, the master device is the one that controls the timing for data exchanges between the cascaded devices and an external interface. The controlled device is called the slave device. microcontroller An integrated circuit chip that is designed primarily for control systems and products. In addition to a CPU, a microcontroller typically includes memory, timing circuits, and IO circuitry. The reason for this is to permit the realization of a controller with a minimal quantity of chips, thus achieving maximal possible miniaturization. This in turn, reduces the volume and the cost of the controller. The microcontroller is normally not used for general-purpose computation as is a microprocessor. mixed-signal The reference to a circuit containing both analog and digital techniques and components. modulator A device that imposes a signal on a carrier. noise 1. A disturbance that affects a signal and that may distort the information carried by the signal. 2. The random variations of one or more characteristics of any entity such as voltage, current, or data. oscillator A circuit that may be crystal controlled and is used to generate a clock frequency. parity A technique for testing transmitting data. Typically, a binary digit is added to the data to make the sum of all the digits of the binary data either always even (even parity) or always odd (odd parity). Phase-locked loop (PLL) An electronic circuit that controls an oscillator so that it maintains a constant phase angle relative to a reference signal. pinouts The pin number assignment: the relation between the logical inputs and outputs of the PSoC device and their physical counterparts in the printed circuit board (PCB) package. Pinouts involve pin numbers as a link between schematic and PCB design (both being computer generated files) and may also involve pin names. Document Number: 38-12036 Rev. *E Page 28 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Glossary (continued) port A group of pins, usually eight. Power on reset (POR) A circuit that forces the PSoC device to reset when the voltage is below a pre-set level. This is one type of hardware reset. PSoC® Cypress Semiconductor’s PSoC® is a registered trademark and Programmable System-onChip™ is a trademark of Cypress. PSoC Designer™ The software for Cypress’ Programmable System-on-Chip technology. pulse width An output in the form of duty cycle which varies as a function of the applied measurand modulator (PWM) RAM An acronym for random access memory. A data-storage device from which data can be read out and new data can be written in. register A storage device with a specific capacity, such as a bit or byte. reset A means of bringing a system back to a know state. See hardware reset and software reset. ROM An acronym for read only memory. A data-storage device from which data can be read out, but new data cannot be written in. serial 1. Pertaining to a process in which all events occur one after the other. 2. Pertaining to the sequential or consecutive occurrence of two or more related activities in a single device or channel. settling time The time it takes for an output signal or value to stabilize after the input has changed from one value to another. shift register A memory storage device that sequentially shifts a word either left or right to output a stream of serial data. slave device A device that allows another device to control the timing for data exchanges between two devices. Or when devices are cascaded in width, the slave device is the one that allows another device to control the timing of data exchanges between the cascaded devices and an external interface. The controlling device is called the master device. SRAM An acronym for static random access memory. A memory device where you can store and retrieve data at a high rate of speed. The term static is used because, after a value is loaded into an SRAM cell, it remains unchanged until it is explicitly altered or until power is removed from the device. SROM An acronym for supervisory read only memory. The SROM holds code that is used to boot the device, calibrate circuitry, and perform Flash operations. The functions of the SROM may be accessed in normal user code, operating from Flash. stop bit A signal following a character or block that prepares the receiving device to receive the next character or block. synchronous 1. A signal whose data is not acknowledged or acted upon until the next active edge of a clock signal. 2. A system whose operation is synchronized by a clock signal. Document Number: 38-12036 Rev. *E Page 29 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Glossary (continued) tri-state A function whose output can adopt three states: 0, 1, and Z (high-impedance). The function does not drive any value in the Z state and, in many respects, may be considered to be disconnected from the rest of the circuit, allowing another output to drive the same net. UART A UART or universal asynchronous receiver-transmitter translates between parallel bits of data and serial bits. user modules Pre-build, pre-tested hardware/firmware peripheral functions that take care of managing and configuring the lower level Analog and Digital PSoC Blocks. User Modules also provide high level API (Application Programming Interface) for the peripheral function. user space The bank 0 space of the register map. The registers in this bank are more likely to be modified during normal program execution and not just during initialization. Registers in bank 1 are most likely to be modified only during the initialization phase of the program. VDD A name for a power net meaning "voltage drain." The most positive power supply signal. Usually 5 V or 3.3 V. VSS A name for a power net meaning "voltage source." The most negative power supply signal. watchdog timer A timer that must be serviced periodically. If it is not serviced, the CPU resets after a specified period of time. Document Number: 38-12036 Rev. *E Page 30 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A Document History Page Document Title: CY8C9520A, CY8C9540A, CY8C9560A, 20, 40, and 60 Bit I/O Expander with EEPROM Document Number: 38-12036 Revision ECN No. Orig. of Change Submission Date Description of Change ** 346754 HMT See ECN New silicon, document. *A 392484 HMT See ECN Correct pin 79 on the TQFP. Add AC PWM Output Jitter spec. table. Upgrade to CY Perform logo and update zip code and trademarks. *B 1336984 HMT/AESA See ECN Update typical and recommended Storage Temperature per industrial specs. Update copyright and trademarks. Add Watchdog timer details. Add “A” to existing part numbers to indicate new firmware. Fix errors. Implement CY template. *C 2843174 YARA 01/08/2010 Added Contents. Updated Overview. Updated Pin 11 description in Figure 2 on page 5. Modified Note 3. Added IOH and IOL specifications in DC GPIO Specifications. Removed “Output Jitter” from AC PWM Specifications section on page 18. Added F24MHzPWM, F32kHzPWM, and F93.5kHzPWM specifications in Table 27. Added Table 29. *D 2903402 NJF 04/01/2010 Updated Cypress website links Added TBAKETEMP and TBAKETIME parameters Updated package diagrams *E 3110285 NJF 12/14/10 Document Number: 38-12036 Rev. *E Added text “When the part is held in reset all In and Out pins are held at their default High-Z State” to section “External Reset Pin (XRES)” on page 9. Added DC I2C Specifications table. Updated Units of Measure, Acronyms, Glossary, and References sections. Updated solder reflow specifications. No specific changes made to I2C Timing Diagram. It has been updated for clearer understanding. Page 31 of 32 [+] Feedback CY8C9520A CY8C9540A, CY8C9560A 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 cypress.com/go/clocks psoc.cypress.com/solutions cypress.com/go/interface PSoC 1 | PSoC 3 | PSoC 5 cypress.com/go/powerpsoc cypress.com/go/plc Memory Optical & Image Sensing cypress.com/go/memory cypress.com/go/image PSoC Touch Sensing cypress.com/go/psoc cypress.com/go/touch USB Controllers Wireless/RF cypress.com/go/USB cypress.com/go/wireless © Cypress Semiconductor Corporation, 2007-2010. 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: 38-12036 Rev. *E Revised December 14, 2010 Page 32 of 32 PSoC Designer™ and Programmable System-on-Chip™ are trademarks and PSoC® and CapSense® are registered trademarks of Cypress Semiconductor Corporation. Purchase of I2C components from Cypress or one of its sublicensed Associated Companies conveys a license under the Philips I2C Patent Rights to use these components in an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips. As from October 1st, 2006 Philips Semiconductors has a new trade name - NXP Semiconductors. All products and company names mentioned in this document may be the trademarks of their respective holders. [+] Feedback