Cypress Computer Hardware CY7C65113C User Manual

CY7C65113C

USB Hub with Microcontroller

Cypress Semiconductor Corporation

Document #: 38-08002 Rev. *D

•

198 Champion Court

•

San Jose, CA 95134-1709

•

408-943-2600

Revised March 6, 2006

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CY7C65113C

16.0 USB HUB .....................................................................................................................................29

16.1 Connecting/Disconnecting a USB Device ..............................................................................29

16.2 Enabling/Disabling a USB Device ..........................................................................................30

16.3 Hub Downstream Ports Status and Control ...........................................................................30

16.4 Downstream Port Suspend and Resume ...............................................................................32

16.5 USB Upstream Port Status and Control .................................................................................33

17.0 USB SERIAL INTERFACE ENGINE OPERATION .....................................................................34

17.1 USB Device Addresses ..........................................................................................................34

17.2 USB Device Endpoints ...........................................................................................................34

17.3 USB Control Endpoint Mode Registers ..................................................................................35

17.4 USB Non-control Endpoint Mode Registers ...........................................................................36

17.5 USB Endpoint Counter Registers ...........................................................................................36

17.6 Endpoint Mode/Count Registers Update and Locking Mechanism ........................................37

18.0 USB MODE TABLES ..................................................................................................................39

19.0 REGISTER SUMMARY ...............................................................................................................43

20.0 SAMPLE SCHEMATIC ................................................................................................................45

21.0 ABSOLUTE MAXIMUM RATINGS ..............................................................................................45

22.0 ELECTRICAL CHARACTERISTICS ...........................................................................................46

23.0 SWITCHING CHARACTERISTICS ..............................................................................................47

24.0 ORDERING INFORMATION .......................................................................................................48

25.0 PACKAGE DIAGRAM .................................................................................................................48

LIST OF FIGURES

Figure 5-1. Program Memory Space with Interrupt Vector Table .........................................................12

Figure 6-1. Clock Oscillator On-Chip Circuit ........................................................................................15

Figure 7-1. Watchdog Reset (Address 0x26) .......................................................................................16

Figure 9-1. Block Diagram of a GPIO Pin ............................................................................................17

Figure 9-2. Port 0 Data ........................................................................................................................17

Figure 9-3. Port1 Data .........................................................................................................................17

Figure 9-4. GPIO Configuration Register .............................................................................................18

Figure 9-5. Port 0 Interrupt Enable .......................................................................................................19

Figure 9-6. Port 1 Interrupt Enable .......................................................................................................19

Figure 10-1. Timer LSB Register .........................................................................................................20

Figure 10-2. Timer MSB Register ........................................................................................................20

Figure 10-3. Timer Block Diagram .......................................................................................................20

Figure 11-1. I²C Configuration Register ...............................................................................................20

Figure 12-1. I²C Data Register .............................................................................................................21

Figure 12-2. I²C Status and Control Register .......................................................................................21

Figure 13-1. Processor Status and Control Register ...........................................................................23

Figure 14-1. Global Interrupt Enable Register .....................................................................................24

Figure 14-2. USB Endpoint Interrupt Enable Register .........................................................................24

Figure 14-3. Interrupt Controller Function Diagram .............................................................................25

Figure 14-4. GPIO Interrupt Structure ..................................................................................................27

Figure 16-1. Hub Ports Connect Status ...............................................................................................29

Figure 16-2. Hub Ports Speed .............................................................................................................30

Figure 16-3. Hub Ports Enable Register ..............................................................................................30

Figure 16-4. Hub Downstream Ports Control Register .........................................................................31

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Figure 16-5. Hub Ports Force Low Register .........................................................................................31

Figure 16-6. Hub Ports SE0 Status Register .......................................................................................31

Figure 16-7. Hub Ports Data Register ..................................................................................................32

Figure 16-8. Hub Ports Suspend Register ...........................................................................................32

Figure 16-9. Hub Ports Resume Status Register .................................................................................33

Figure 16-10. USB Status and Control Register ..................................................................................33

Figure 17-1. USB Device Address Registers .......................................................................................34

Figure 17-2. USB Device Endpoint Zero Mode Registers ....................................................................35

Figure 17-3. USB Non-control Device Endpoint Mode Registers ........................................................36

Figure 17-4. USB Endpoint Counter Registers ....................................................................................36

Figure 17-5. Token/Data Packet Flow Diagram ...................................................................................38

LIST OF TABLES

Table 4-1. Pin Assignments ...................................................................................................................8

Table 4-2. I/O Register Summary ..........................................................................................................9

Table 4-3. Instruction Set Summary .....................................................................................................10

Table 9-1. GPIO Port Output Control Truth Table and Interrupt Polarity .............................................19

Table 11-1. I²C Port Configuration .......................................................................................................20

Table 12-1. I²C Status and Control Register Bit Definitions .................................................................21

Table 14-1. Interrupt Vector Assignments ............................................................................................26

Table 16-1. Control Bit Definition for Downstream Ports .....................................................................31

Table 16-2. Control Bit Definition for Upstream Port ............................................................................34

Table 17-1. Memory Allocation for Endpoints .....................................................................................35

Table 18-1. USB Register Mode Encoding ..........................................................................................39

Table 18-2. Decode table for Table 18-3: “Details of Modes for Differing Traffic Condition .................40

Table 18-3. Details of Modes for Differing Traffic Conditions ...............................................................41

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CY7C65113C

1.0

Features

• Full Speed USB hub with an integrated microcontroller

• 8-bit USB optimized microcontroller

— Harvard architecture

— 6-MHz external clock source

— 12-MHz internal CPU clock

— 48-MHz internal hub clock

• Internal memory

— 256 bytes of RAM

— 8 KB of PROM

• Integrated Master/Slave I C-compatible Controller (100 kHz) enabled through General-purpose I/O (GPIO) pins

• I/O ports

— Two GPIO ports (Port 0 to 2) capable of sinking 7 mA per pin (typical)

— Higher current drive achievable by connecting multiple GPIO pins together to drive a common output

— EachGPIOport can be configured asinputs withinternalpull-ups or open drain outputsor traditional CMOS outputs

— Maskable interrupts on all I/O pins

• 12-bit free-running timer with one microsecond clock ticks

• Watchdog timer (WDT)

• Internal Power-on Reset (POR)

• USB Specification compliance

— Conforms to USB Specification, Version 1.1

— Conforms to USB HID Specification, Version 1.1

—Supports one or two device addresses with up to 5 user-configured endpoints

Up to two 8-byte control endpoints

Up to four 8-byte data endpoints

Up to two 32-byte data endpoints

— Integrated USB transceivers

—Supports four downstream USB ports

— GPIO pins can provide individual power control outputs for each downstream USB port

— GPIO pins can provide individual port over current inputs for each downstream USB port

• Improved output drivers to reduce electromagnetic interference (EMI)

• Operating voltage from 4.0V to 5.5V DC

• Operating temperature from 0° to 70° C

• Available in 28-pin SOIC (-SXC) package

• Industry-standard programmer support.

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CY7C65113C

2.0

Functional Overview

The CY7C65113C device is a one-time programmable 8-bit microcontroller with a built-in 12-Mbps USB hub that supports up to

four downstream ports. The microcontroller instruction set has been optimized specifically for USB operations, although the

microcontrollers can be used for a variety of non-USB embedded applications.

GPIO

The CY7C65113C has 11 GPIO pins (P0[7:0], P1[2:0]), both rated at 7 mA per pin (typical) sink current. Multiple GPIO pins can

be connected together to drive a single output for more drive current capacity.

Clock

The microcontroller uses an external 6-MHz crystal and an internal oscillator to provide a reference to an internal phase-locked

loop (PLL)-based clock generator. This technology allows the customer application to use an inexpensive 6-MHz fundamental

crystal that reduces the clock-related noise emissions (EMI). A PLL clock generator provides the 6-, 12-, and 48-MHz clock signals

for distribution within the microcontroller.

Memory

The CY7C65113C is offered with 8 KB of PROM.

Power-on Reset, Watchdog, and Free-running Timer

These parts include power-on reset logic, a Watchdog timer, and a 12-bit free-running timer. The POR logic detects when power

is applied to the device, resets the logic to a known state, and begins executing instructions at PROM address 0x0000. The

Watchdog timer is used to ensure the microcontroller recovers after a period of inactivity. The firmware may become inactive for

a variety of reasons, including errors in the code or a hardware failure such as waiting for an interrupt that never occurs.

I C

The microcontroller can communicate with external electronics through the GPIO pins. An I C-compatible interface accommo-

dates a 100-kHz serial link with an external device.

Timer

The free-running 12-bit timer clocked at 1 MHz provides two interrupt sources, 128-µs and 1.024-ms. The timer can be used to

measure the duration of an event under firmware control by reading the timer at the start of the event and after the event is

complete. The difference between the two readings indicates the duration of the event in microseconds. The upper four bits of

the timer are latched into an internal register when the firmware reads the lower eight bits. A read from the upper four bits actually

reads data from the internal register, instead of the timer. This feature eliminates the need for firmware to try to compensate if the

upper four bits increment immediately after the lower eight bits are read.

Interrupts

The microcontroller supports ten maskable interrupts in the vectored interrupt controller. Interrupt sources include the USB Bus

Reset interrupt, the 128-µs (bit 6) and 1.024-ms (bit 9) outputs from the free-running timer, five USB endpoints, the USB hub, the

GPIO ports, and the I C-compatible master mode interface. The timer bits cause an interrupt (if enabled) when the bit toggles

from LOW ‘0’ to HIGH ‘1’. The USB endpoints interrupt after the USB host has written data to the endpoint FIFO or after the USB

controller sends a packet to the USB host. The GPIO ports also have a level of masking to select which GPIO inputs can cause

a GPIO interrupt. Input transition polarity can be programmed for each GPIO port as part of the port configuration. The interrupt

polarity can be rising edge (‘0’ to ‘1’) or falling edge (‘1’ to ‘0’).

USB

The CY7C65113C includes an integrated USB Serial Interface Engine (SIE) that supports the integrated peripherals and the hub

controller function. The hardware supports up to two USB device addresses with one device address for the hub (two endpoints)

and a device address for a compound device (three endpoints). The SIE allows the USB host to communicate with the hub and

functions integrated into the microcontroller. The CY7C65113C part includes a 1:4 hub repeater with one upstream port and four

downstream ports. The USB Hub allows power management control of the downstream ports by using GPIO pins assigned by

the user firmware. The user has the option of ganging the downstream ports together with a single pair of power management

pins, or providing power management for each port with four pairs of power management pins.

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Logic Block Diagram

6-MHz crystal

USB

Transceiver

D+[0]

D–[0]

Upstream

USB Port

Downstream USB Ports

PLL

USB

Transceiver

D+[1]

D–[1]

48 MHz

Clock

12-MHz

8-bit

CPU

USB

Transceiver

Divider

D+[2]

D–[2]

12 MHz

Repeater

USB

SIE

USB

Transceiver

PROM

8 KB

D+[3]

D–[3]

USB

Transceiver

RAM

256 byte

Interrupt

Controller

D+[4]

D–[4]

6 MHz

Power management under firmware

control using GPIO pins

12-bit

Timer

P0[0]

P0[7]

GPIO

PORT 0

Watchdog

Timer

P1[0]

P1[2]

GPIO

PORT 1

Power-on

Reset

SCLK

SDATA

I C comp.

Interface

*I C-compatible interface enabled by firmware through

P1[1:0]

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3.0

Pin Configurations

Top View

CY7C65113C

28-pin SOIC

XTALOUT

XTALIN

P1[1]

P1[0]

P1[2]

D–[3]

D+[3]

D–[4]

D+[4]

REF

GND

D+[0]

D–[0]

D+[1]

D–[1]

D+[2]

D–[2]

P0[7]

P0[5]

P0[3]

P0[1]

GND

P0[0]

P0[2]

P0[4]

P0[6]

4.0

4.1

Product Summary Tables

Pin Assignments

Table 4-1. Pin Assignments

Name

I/O

28-pin

Description

D+[0], D–[0]

D+[1], D–[1]

D+[2], D–[2]

D+[3], D–[3]

D+[4], D–[4]

5, 6

Upstream port, USB differential data.

7, 8

Downstream Port 1, USB differential data.

Downstream Port 2, USB differential data.

Downstream Port 3, USB differential data.

Downstream Port 4, USB differential data.

GPIO Port 0 capable of sinking 7 mA (typical).

9, 10

23, 24

21, 22

P1[7:0]

11, 15, 12, 16, 13, 17, 14, 18

I/O

P1[2:0]

25, 27, 26

GPIO Port 1 capable of sinking 7 mA (typical).

XTAL

6-MHz crystal or external clock input.

6-MHz crystal out.

OUT

4, 20

Programming voltage supply, tie to ground during normal operation.

Voltage supply.

Ground.

GND

External 3.3V supply voltage for the downstream differential data output

buffers and the D+ pull-up.

REF

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4.2

I/O Register Summary

I/O registers are accessed via the I/O Read (IORD) and I/O Write (IOWR, IOWX) instructions. IORD reads data from the selected

port into the accumulator. IOWR performs the reverse; it writes data from the accumulator to the selected port. Indexed I/O Write

(IOWX) adds the contents of X to the address in the instruction to form the port address and writes data from the accumulator to

the specified port. Specifying address 0 (e.g., IOWX 0h) means the I/O register is selected solely by the contents of X.

All undefined registers are reserved. Do not write to reserved registers as this may cause an undefined operation or increased

current consumption during operation. When writing to registers with reserved bits, the reserved bits must be written with ‘0.’

Table 4-2. I/O Register Summary

Port 0 Data

I/O Address Read/Write

Function

Page

0x00

0x01

0x04

0x05

0x08

0x09

0x10

0x11

R/W

GPIO Port 0 Data

GPIO Port 1 Data

Port 1 Data

Port 0 Interrupt Enable

Port 1 Interrupt Enable

GPIO Configuration

Interrupt Enable for Pins in Port 0

Interrupt Enable for Pins in Port 1

GPIO Port Configurations

R/W

I C Configuration

I C Position Configuration

USB Device Address A

EP A0 Counter Register

EP A0 Mode Register

EP A1 Counter Register

EP A1 Mode Register

EP A2 Counter Register

EP A2 Mode Register

USB Status & Control

Global Interrupt Enable

Endpoint Interrupt Enable

Interrupt Vector

USB Device Address A

USB Address A, Endpoint 0 Counter

USB Address A, Endpoint 0 Configuration

USB Address A, Endpoint 1 Counter

USB Address A, Endpoint 1 Configuration

USB Address A, Endpoint 2 Counter

USB Address A, Endpoint 2 Configuration

USB Upstream Port Traffic Status and Control

Global Interrupt Enable

0x12

0x13

0x14

0x15

0x16

0x1F

0x20

0x21

0x23

0x24

0x25

0x26

0x28

0x29

0x30

0x31

0x32

0x38-0x3F

0x40

0x41

0x42

USB Endpoint Interrupt Enables

Pending Interrupt Vector Read/Clear

Lower Eight Bits of Free-running Timer (1 MHz)

Upper Four Bits of Free-running Timer

Watchdog Reset Clear

Timer (LSB)

Timer (MSB)

WDR Clear

I C Control & Status

R/W

I C Status and Control

I C Data

Reserved

USB Device Address B

EP B0 Counter Register

EP B0 Mode Register

R/W

USB Device Address B (not used in 5-endpoint mode) 34

USB Address B, Endpoint 0 Counter

USB Address B, Endpoint 0 Configuration, or

USB Address A, Endpoint 3 in 5-endpoint mode

EP B1 Counter Register

EP B1 Mode Register

0x43

0x44

R/W

USB Address B, Endpoint 1 Counter

USB Address B, Endpoint 1 Configuration, or

USB Address A, Endpoint 4 in 5-endpoint mode

Hub Port Connect Status

Hub Port Enable

0x48

0x49

0x4A

R/W

Hub Downstream Port Connect Status

Hub Downstream Ports Enable

Hub Downstream Ports Speed

Hub Port Speed

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Table 4-2. I/O Register Summary (continued)

Hub Port Control (Ports [4:1])

Hub Port Suspend

I/O Address Read/Write

Function

Page

0x4B

0x4D

0x4E

0x4F

0x50

0x51

0xFF

R/W

Hub Downstream Ports Control (Ports [4:1])

Hub Downstream Port Suspend Control

Hub Downstream Ports Resume Status

Hub Downstream Ports SE0 Status

Hub Port Resume Status

Hub Ports SE0 Status

Hub Ports Data

Hub Downstream Ports Differential Data

Hub Downstream Ports Force LOW (Ports [1:4])

Microprocessor Status and Control Register

Hub Downstream Force Low

Processor Status & Control

R/W

4.3

Instruction Set Summary

Refer to the CYASM Assembler User’s Guide for more details. Note that conditional jump instructions (i.e., JC, JNC, JZ, JNZ)

take five cycles if jump is taken, four cycles if no jump.

Table 4-3. Instruction Set Summary

MNEMONIC

HALT

operand

opcode

cycles

MNEMONIC

NOP

operand

acc

opcode

cycles

ADD A,expr

data

INC A

ADD A,[expr]

ADD A,[X+expr]

ADC A,expr

direct

index

data

INC X

INC [expr]

INC [X+expr]

DEC A

direct

index

acc

ADC A,[expr]

ADC A,[X+expr]

SUB A,expr

direct

index

data

DEC X

DEC [expr]

DEC [X+expr]

IORD expr

IOWR expr

POP A

direct

index

address

SUB A,[expr]

SUB A,[X+expr]

SBB A,expr

direct

index

data

SBB A,[expr]

SBB A,[X+expr]

OR A,expr

direct

index

data

POP X

PUSH A

OR A,[expr]

direct

index

data

PUSH X

OR A,[X+expr]

AND A,expr

SWAP A,X

SWAP A,DSP

MOV [expr],A

MOV [X+expr],A

OR [expr],A

OR [X+expr],A

AND [expr],A

AND [X+expr],A

XOR [expr],A

XOR [X+expr],A

IOWX [X+expr]

CPL

AND A,[expr]

AND A,[X+expr]

XOR A,expr

direct

index

data

direct

index

direct

index

direct

index

direct

index

XOR A,[expr]

XOR A,[X+expr]

CMP A,expr

CMP A,[expr]

CMP A,[X+expr]

MOV A,expr

MOV A,[expr]

MOV A,[X+expr]

MOV X,expr

MOV X,[expr]

reserved

direct

index

data

direct

index

data

direct

index

data

ASL

ASR

direct

RLC

RRC

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Table 4-3. Instruction Set Summary (continued)

MNEMONIC operand opcode cycles

XPAGE 1F

MNEMONIC

RET

operand

opcode

cycles

MOV A,X

MOV X,A

MOV PSP,A

CALL

RETI

addr

50-5F

80-8F

90-9F

A0-AF

B0-BF

addr

C0-CF

D0-DF

E0-EF

F0-FF

5 (or 4)

JMP

addr

JNC

JACC

INDEX

addr

CALL

5 (or 4)

JNZ

5.0

5.1

Programming Model

14-bit Program Counter

The 14-bit Program Counter (PC) allows access to up to 8 KB of PROM available with the CY7C65113C architecture. The top

32 bytes of the ROM in the 8K part are reserved for testing purposes. The program counter is cleared during reset, such that the

first instruction executed after a reset is at address 0x0000h. Typically, this is a jump instruction to a reset handler that initializes

the application (see Interrupt Vectors on page 25).

The lower eight bits of the program counter are incremented as instructions are loaded and executed. The upper six bits of the

program counter are incremented by executing an XPAGE instruction. As a result, the last instruction executed within a 256-byte

“page” of sequential code should be an XPAGE instruction. The assembler directive “XPAGEON” causes the assembler to insert

XPAGE instructions automatically. Because instructions can be either one or two bytes long, the assembler may occasionally

need to insert a NOP followed by an XPAGE to execute correctly.

The address of the next instruction to be executed, the carry flag, and the zero flag are saved as two bytes on the program stack

during an interrupt acknowledge or a CALL instruction. The program counter, carry flag, and zero flag are restored from the

program stack during a RETI instruction. Only the program counter is restored during a RET instruction.

The program counter cannot be accessed directly by the firmware. The program stack can be examined by reading SRAM from

location 0x00 and up.

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5.1.1

Program Memory Organization

after reset

14-bit PC

Address

0x0000

Program execution begins here after a reset

0x0002

0x0004

0x0006

0x0008

0x000A

0x000C

0x000E

0x0010

0x0012

0x0014

0x0016

0x0018

0x001A

USB Bus Reset interrupt vector

128-µs timer interrupt vector

1.024-ms timer interrupt vector

USB address A endpoint 0 interrupt vector

USB address A endpoint 1 interrupt vector

USB address A endpoint 2 interrupt vector

USB address B endpoint 0 interrupt vector

USB address B endpoint 1 interrupt vector

Hub interrupt vector

Reserved

GPIO interrupt vector

I C interrupt vector

Program Memory begins here

0x1FDF

(8 KB -32) PROM ends here (CY7C65113C)

Figure 5-1. Program Memory Space with Interrupt Vector Table

Note that the upper 32 bytes of the 8K PROM are reserved. Therefore, user’s program must not overwrite this space.

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5.2

8-bit Accumulator (A)

The accumulator is the general-purpose register for the microcontroller.

5.3

8-bit Temporary Register (X)

The “X” register is available to the firmware for temporary storage of intermediate results. The microcontroller can perform indexed

operations based on the value in X. Refer to Section 5.6.3 for additional information.

5.4

8-bit Program Stack Pointer (PSP)

During a reset, the Program Stack Pointer (PSP) is set to 0x00 and “grows” upward from this address. The PSP may be set by

firmware, using the MOV PSP,A instruction. The PSP supports interrupt service under hardware control and CALL, RET, and

RETI instructions under firmware control. The PSP is not readable by the firmware.

During an interrupt acknowledge, interrupts are disabled and the 14-bit program counter, carry flag, and zero flag are written as

two bytes of data memory. The first byte is stored in the memory addressed by the PSP, then the PSP is incremented. The second

byte is stored in memory addressed by the PSP, and the PSP is incremented again. The overall effect is to store the program

counter and flags on the program “stack” and increment the PSP by two.

The Return From Interrupt (RETI) instruction decrements the PSP, then restores the second byte from memory addressed by the

PSP. The PSP is decremented again and the first byte is restored from memory addressed by the PSP. After the program counter

and flags have been restored from stack, the interrupts are enabled. The overall effect is to restore the program counter and flags

from the program stack, decrement the PSP by two, and re-enable interrupts.

The Call Subroutine (CALL) instruction stores the program counter and flags on the program stack and increments the PSP by

two.

The Return From Subroutine (RET) instruction restores the program counter but not the flags from the program stack and

decrements the PSP by two.

5.4.1

Data Memory Organization

The CY7C65113C microcontrollers provide 256 bytes of data RAM. Normally, the SRAM is partitioned into four areas: program

stack, user variables, data stack, and USB endpoint FIFOs. The following is one example of where the program stack, data stack,

and user variables areas could be located.

After reset

8-bit DSP 8-bit PSP

Address

0x00

Program Stack Growth

[1]

(Move DSP

)

user selected

Data Stack Growth

8-bit DSP

User variables

[2]

USB FIFO space for up to two Addresses and five endpoints

0xFF

Notes:

1. Refer to Section 5.5 for a description of DSP.

2. Endpoint sizes are fixed by the Endpoint Size Bit (I/O register 0x1F, Bit 7). See T a ble 17-1.

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5.5

8-bit Data Stack Pointer (DSP)

The Data Stack Pointer (DSP) supports PUSH and POP instructions that use the data stack for temporary storage. A PUSH

instruction pre-decrements the DSP, then writes data to the memory location addressed by the DSP. A POP instruction reads

data from the memory location addressed by the DSP, then post-increments the DSP.

During a reset, the DSP is reset to 0x00. A PUSH instruction when DSP equals 0x00 writes data at the top of the data RAM

(address 0xFF). This writes data to the memory area reserved for USB endpoint FIFOs. Therefore, the DSP should be indexed

at an appropriate memory location that does not compromise the Program Stack, user-defined memory (variables), or the USB

endpoint FIFOs.

For USB applications, the firmware should set the DSP to an appropriate location to avoid a memory conflict with RAM dedicated

to USB FIFOs. The memory requirements for the USB endpoints are described in Section 17.2. Example assembly instructions

to do this with two device addresses (FIFOs begin at 0xD8) are shown below:

MOV A,20h

; Move 20 hex into Accumulator (must be D8h or less)

SWAP A,DSP ; swap accumulator value into DSP register.

5.6

Address Modes

The CY7C65113 microcontrollers support three addressing modes for instructions that require data operands: data, direct, and

indexed.

5.6.1

Data (Immediate)

“Data” address mode refers to a data operand that is actually a constant encoded in the instruction. As an example, consider the

instruction that loads A with the constant 0xD8:

• MOV A, 0D8h.

This instruction requires two bytes of code where the first byte identifies the “MOV A” instruction with a data operand as the

second byte. The second byte of the instruction is the constant “0xD8.” A constant may be referred to by name if a prior “EQU”

statement assigns the constant value to the name. For example, the following code is equivalent to the example shown above:

• DSPINIT: EQU 0D8h

• MOV A, DSPINIT.

5.6.2

Direct

“Direct” address mode is used when the data operand is a variable stored in SRAM. In that case, the one byte address of the

variable is encoded in the instruction. As an example, consider an instruction that loads A with the contents of memory address

location 0x10:

• MOV A, [10h].

Normally, variable names are assigned to variable addresses using “EQU” statements to improve the readability of the assembler

source code. As an example, the following code is equivalent to the example shown above:

• buttons: EQU 10h

• MOV A, [buttons].

5.6.3

Indexed

“Indexed” address mode allows the firmware to manipulate arrays of data stored in SRAM. The address of the data operand is

the sum of a constant encoded in the instruction and the contents of the “X” register. Normally, the constant is the “base” address

of an array of data and the X register contains an index that indicates which element of the array is actually addressed:

• array: EQU 10h

• MOV X, 3

• MOV A, [X+array].

This would have the effect of loading A with the fourth element of the SRAM “array” that begins at address 0x10. The fourth

element would be at address 0x13.

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6.0

Clocking

XTALOUT

(pin 1)

XTALIN

(pin 2)

To Internal PLL

30 pF

Figure 6-1. Clock Oscillator On-Chip Circuit

The XTALIN and XTALOUT are the clock pins to the microcontroller. The user can connect an external oscillator or a crystal to

these pins. When using an external crystal, keep PCB traces between the chip leads and crystal as short as possible (less than

2 cm). A 6-MHz fundamental frequency parallel resonant crystal can be connected to these pins to provide a reference frequency

for the internal PLL. The two internal 30-pF load caps appear in series to the external crystal and would be equivalent to a 15-pF

load. Therefore, the crystal must have a required load capacitance of about 15–18 pF. A ceramic resonator does not allow the

microcontroller to meet the timing specifications of full speed USB and therefore a ceramic resonator is not recommended with

these parts.

An external 6-MHz clock can be applied to the XTALIN pin if the XTALOUT pin is left open. Grounding the XTALOUT pin when

driving XTALIN with an oscillator does not work because the internal clock is effectively shorted to ground.

7.0

Reset

The CY7C65113C supports two resets: POR and WDR. Each of these resets causes:

• all registers to be restored to their default states

• the USB device addresses to be set to 0

• all interrupts to be disabled

• the PSP and DSP to be set to memory address 0x00.

The occurrence of a reset is recorded in the Processor Status and Control Register, as described in Section. Bits 4 and 6 are

used to record the occurrence of POR and WDR respectively. Firmware can interrogate these bits to determine the cause of a

reset.

Program execution starts at ROM address 0x0000 after a reset. Although this looks like interrupt vector 0, there is an important

difference. Reset processing does NOT push the program counter, carry flag, and zero flag onto program stack. The firmware

reset handler should configure the hardware before the “main” loop of code. Attempting to execute a RET or RETI in the firmware

reset handler causes unpredictable execution results.

7.1

Power-on Reset

When V is first applied to the chip, the POR signal is asserted and the CY7C65113C enters a “semi-suspend” state. During

the semi-suspend state, which is different from the suspend state defined in the USB specification, the oscillator and all other

blocks of the part are functional, except for the CPU. This semi-suspend time ensures that both a valid V level is reached and

that the internal PLL has time to stabilize before full operation begins. When the V has risen above approximately 2.5V, and

the oscillator is stable, the POR is deasserted and the on-chip timer starts counting. The first 1 ms of suspend time is not

interruptible, and the semi-suspend state continues for an additional 95 ms unless the count is bypassed by a USB Bus Reset

on the upstream port. The 95 ms provides time for V to stabilize at a valid operating voltage before the chip executes code.

If a USB Bus Reset occurs on the upstream port during the 95 ms semi-suspend time, the semi-suspend state is aborted and

program execution begins immediately from address 0x0000. In this case, the Bus Reset interrupt is pending but not serviced

until firmware sets the USB Bus Reset Interrupt Enable bit (Bit 0, Figure 14-1) and enables interrupts with the EI command.

The POR signal is asserted whenever V drops below approximately 2.5V, and remains asserted until V rises above this level

again. Behavior is the same as described above.

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7.2

The WDR occurs when the internal Watchdog Timer rolls over. Writing any value to the write-only Watchdog Reset Clear Register

(Figure 7-1) clears the timer. The timer rolls over and WDR occurs if it is not cleared within t of the last clear (see Section

Watchdog Reset

WATCH

23.0 for the value of t

). Bit 6 of the Processor Status and Control Register (Figure 13-1) is set to record this event (the

WATCH

register contents are set to 010X0001 by the WDR). A Watchdog Timer Reset lasts for 2 ms, after which the microcontroller begins

execution at ROM address 0x0000.

2 ms

WATCH

Last write to

Watchdog Timer

No write to WDT

goes HIGH

Execution begins at

Reset Vector 0x0000

Figure 7-1. Watchdog Reset (Address 0x26)

The USB transmitter is disabled by a Watchdog Reset because the USB Device Address Registers are cleared (see Section

17.1). Otherwise, the USB Controller would respond to all address 0 transactions.

It is possible for the WDR bit of the Processor Status and Control Register (Figure 13-1) to be set following a POR event. If a

firmware interrogates the Processor Status and Control Register for a set condition on the WDR bit, the WDR bit should be ignored

if the POR bit is set (Bit 3 of the Processor Status and Control Register).

8.0

Suspend Mode

The CY7C65113C can be placed into a low-power state by setting the Suspend bit of the Processor Status and Control register.

All logic blocks in the device are turned off except the GPIO interrupt logic and the USB receiver. The clock oscillator and PLL,

as well as the free-running and Watchdog timers, are shut down. Only the occurrence of an enabled GPIO interrupt or non-idle

bus activity at a USB upstream or downstream port wakes the part out of suspend. The Run bit in the Processor Status and

Control Register must be set to resume a part out of suspend.

The clock oscillator restarts immediately after exiting suspend mode. The microcontroller returns to a fully functional state 1 ms

after the oscillator is stable. The microcontroller executes the instruction following the I/O write that placed the device into suspend

mode before servicing any interrupt requests.

The GPIO interrupt allows the controller to wake-up periodically and poll system components while maintaining a very low average

power consumption. To achieve the lowest possible current during suspend mode, all I/O should be held at V or Gnd. Note:

This also applies to internal port pins that may not be bonded in a particular package.

Typical code for entering suspend is shown below:

...

; All GPIO set to low-power state (no floating pins)

; Enable GPIO interrupts if desired for wake-up

; Set suspend and run bits

; Write to Status and Control Register – Enter suspend, wait for USB activity (or GPIO Interrupt)

; This executes before any ISR

mov a, 09h

iowr FFh

nop

...

; Remaining code for exiting suspend routine.

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9.0

General-purpose I/O Ports

GPIO

CFG

mode

2-bits

Data

Out

Latch

Internal

Data Bus

14 kΩ

GPIO

Port Write

Port Read

Q3*

Data

Latch

Reg_Bit

STRB

(Latch is Transparent)

Data

Interrupt

Latch

Interrupt

Enable

Interrupt

Controller

*Port 0,1: Low I

sink

Figure 9-1. Block Diagram of a GPIO Pin

There are 11 GPIO pins (P0[7:0] and P1[2:0]) for the hardware interface. Each port can be configured as inputs with internal

pull-ups, open drain outputs, or traditional CMOS outputs. The data for each GPIO port is accessible through the data registers.

Port data registers are shown in Figure 9-2 through Figure 9-3, and are set to 1 on reset.

Port 0 Data

Address 0x00

Bit #

Bit Name

Read/Write

Reset

P0.7

R/W

P0.6

R/W

P0.5

R/W

P0.4

R/W

P0.3

R/W

P0.2

R/W

P0.1

R/W

P0.0

R/W

Figure 9-2. Port 0 Data

Port 1 Data

Bit #

Address 0x01

Bit Name

Read/Write

Reset

P1.2

R/W

P1.1

R/W

P1.0

R/W

Figure 9-3. Port1 Data

Special care should be taken with any unused GPIO data bits. An unused GPIO data bit, either a pin on the chip or a port bit that

is not bonded on a particular package, must not be left floating when the device enters the suspend state. If a GPIO data bit is

left floating, the leakage current caused by the floating bit may violate the suspend current limitation specified by the USB

Specifications. If a ‘1’ is written to the unused data bit and the port is configured with open drain outputs, the unused data bit

remains in an indeterminate state. Therefore, if an unused port bit is programmed in open-drain mode, it must be written with a ‘0.’

A read from a GPIO port always returns the present state of the voltage at the pin, independent of the settings in the Port Data

Registers. During reset, all of the GPIO pins are set to a high-impedance input state. Writing a ‘0’ to a GPIO pin drives the pin

LOW. In this state, a ‘0’ is always read on that GPIO pin unless an external source overdrives the internal pull-down device.

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9.1

GPIO Configuration Port

Every GPIO port can be programmed as inputs with internal pull-ups, outputs LOW or HIGH, or Hi-Z (floating, the pin is not driven

internally). In addition, the interrupt polarity for each port can be programmed. The Port Configuration bits (Figure 9-4) and the

Interrupt Enable bit (Figure 9-5 through Figure 9-6) determine the interrupt polarity of the port pins

GPIO Configuration

Address 0x08

Bit #

Bit Name

Reserved

Port 1

Port 0

Config Bit 1 Config Bit 0 Config Bit 1 Config Bit 0

Read/Write

Reset

R/W

Figure 9-4. GPIO Configuration Register

As shown in Table 9-1 below, a positive polarity on an input pin represents a rising edge interrupt (LOW to HIGH), and a negative

polarity on an input pin represents a falling edge interrupt (HIGH to LOW).

The GPIO interrupt is generated when all of the following conditions are met: the Interrupt Enable bit of the associated Port

Interrupt Enable Register is enabled, the GPIO Interrupt Enable bit of the Global Interrupt Enable Register (Figure 14-1) is

enabled, the Interrupt Enable Sense (bit 2, Figure 13-1) is set, and the GPIO pin of the port sees an event matching the interrupt

polarity.

The driving state of each GPIO pin is determined by the value written to the pin’s Data Register (Figure 9-2 through Figure 9-3)

and by its associated Port Configuration bits as shown in the GPIO Configuration Register (Figure 9-4). These ports are

configured on a per-port basis, so all pins in a given port are configured together. The possible port configurations are detailed

in Table 9-1. As shown in this table below, when a GPIO port is configured with CMOS outputs, interrupts from that port are

disabled.

During reset, all of the bits in the GPIO Configuration Register are written with ‘0’ to select Hi-Z mode for all GPIO ports as the

default configuration.

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Table 9-1. GPIO Port Output Control Truth Table and Interrupt Polarity

Port Config Bit 1 Port Config Bit 0 Data Register Output Drive Strength Interrupt Enable Bit

Interrupt Polarity

Disabled

Output LOW

Resistive

– (Falling Edge)

Disabled

Output LOW

Output HIGH

Output LOW

Hi-Z

Disabled

– (Falling Edge)

Disabled

Output LOW

Hi-Z

+ (Rising Edge)

Q1, Q2, and Q3 discussed below are the transistors referenced in Figure 9-1. The available GPIO drive strength are:

• Output LOW Mode: The pin’s Data Register is set to ‘0.’

Writing ‘0’ to the pin’s Data Register puts the pin in output LOW mode, regardless of the contents of the Port Configuration

Bits[1:0]. In this mode, Q1 and Q2 are OFF. Q3 is ON. The GPIO pin is driven LOW through Q3.

• Output HIGH Mode: The pin’s Data Register is set to 1 and the Port Configuration Bits[1:0] is set to ‘10.’

In this mode, Q1 and Q3 are OFF. Q2 is ON. The GPIO is pulled up through Q2. The GPIO pin is capable of sourcing... of

current.

• Resistive Mode: The pin’s Data Register is set to 1 and the Port Configuration Bits[1:0] is set to ‘11.’

Q2 and Q3 are OFF. Q1 is ON. The GPIO pin is pulled up with an internal 14kΩ resistor. In resistive mode, the pin may serve

as an input. Reading the pin’s Data Register returns a logic HIGH if the pin is not driven LOW by an external source.

• Hi-Z Mode: The pin’s Data Register is set to1 and Port Configuration Bits[1:0] is set either ‘00’ or ‘01.’

Q1, Q2, and Q3 are all OFF. The GPIO pin is not driven internally. In this mode, the pin may serve as an input. Reading the

Port Data Register returns the actual logic value on the port pins.

9.2

GPIO Interrupt Enable Ports

Each GPIO pin can be individually enabled or disabled as an interrupt source. The Port 0–1 Interrupt Enable Registers provide

this feature with an Interrupt Enable bit for each GPIO pin.

During a reset, GPIO interrupts are disabled by clearing all of the GPIO Interrupt Enable bits. Writing a ‘1’ to a GPIO Interrupt

Enable bit enables GPIO interrupts from the corresponding input pin. All GPIO pins share a common interrupt, as discussed in

Section 14.7.

Port 0 Interrupt Enable

Address 0x04

Bit #

Bit Name

P0.7 Intr

Enable

P0.6 Intr

Enable

P0.5 Intr

Enable

P0.4 Intr

Enable

P0.3 Intr

Enable

P0.2 Intr

Enable

P0.1 Intr

Enable

P0.0 Intr

Enable

Read/Write

Reset

Figure 9-5. Port 0 Interrupt Enable

Port 1 Interrupt Enable

Address 0x05

Bit #

Bit Name

Reserved

P0.2 Intr

Enable

P1.1 Intr

Enable

P1.0 Intr

Enable

Read/Write

Reset

Figure 9-6. Port 1 Interrupt Enable

10.0

12-bit Free-Running Timer

The 12-bit timer operates with a 1-µs tick, provides two interrupts (128 µs and 1.024 ms) and allows the firmware to directly time

events that are up to 4 ms in duration. The lower eight bits of the timer can be read directly by the firmware. Reading the lower

eight bits latches the upper four bits into a temporary register. When the firmware reads the upper four bits of the timer, it is actually

reading the count stored in the temporary register. The effect of this is to ensure a stable 12-bit timer value can be read, even

when the two reads are separated in time.

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Timer LSB

Bit #

Address 0x24

Bit Name

Read/Write

Reset

Timer Bit 7

TimerBit 6

Timer Bit 5 Timer Bit 4 Timer Bit 3 Timer Bit 2 Timer Bit 1 Timer Bit 0

Figure 10-1. Timer LSB Register

Bit [7:0]: Timer lower eight bits.

Timer MSB

Address 0x25

Bit #

Bit Name

Read/Write

Reset

Reserved

Reserved Timer Bit 11 Timer Bit 10 Timer Bit 9 Timer Bit 8

–

Figure 10-2. Timer MSB Register

Bit [3:0]: Timer higher nibble

Bit [7:4]: Reserved.

1.024-ms interrupt

128-µs interrupt

1 MHz clock

11 10 9

L3 L2 L1 L0

D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0

To Timer Registers

Figure 10-3. Timer Block Diagram

11.0

I²C Configuration Register

Internal hardware supports commu nication with external devices through an I C-compatible interface. I C-compatible function is

[3]

discussed in detail in Section 12.0. The I C Position bit (Bit 7, Figure 11-1) and I C Port Width bit (Bit 1, Figure 11-1) select the

locations of the SCL (clock) and SDA (data) pins on Port 1 as shown in Table 11-1. These bits are cleared on reset. When the

GPIO is configured for I C function, the internal pull ups on the pins are disabled. Addition of an external weak pull-up resistors

on SCL and SDA is recommended.

I C Configuration

Address 0x09

Bit #

Bit Name

I C Position Reserved

Reserved

I C Port

Width

Reserved

Read/Write

Reset

R/W

Figure 11-1. I C Configuration Register

Table 11-1. I C Port Configuration

I C Position (Bit7, Figure 11-1)

I C Port Width (Bit1, Figure 11-1)

I C Position

I C on P1[1:0], 0:SCL, 1:SDA

Note:

3. I C-compatible function must be separately enabled, as described in Section 12.0.

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12.0

I2C-compatible Controller

The I2C-compatible block provides a versatile two-wire communication with external devices, supporting master, slave, and

multi-master modes of operation. The I2C-compatible block functions by handling the low-level signaling in hardware, and issuing

interrupts as needed to allow firmware to take appropriate action during transactions. While waiting for firmware response, the

hardware keeps the I2C-compatible bus idle if necessary.

The I2C-compatible block generates an interrupt to the microcontroller at the end of each received or transmitted byte, when a

stop bit is detected by the slave when in receive mode, or when arbitration is lost. Details of the interrupt responses are given in

Section 14.8.

The I2C-compatible interface consists of two registers, an I C Data Register (Figure 12-1) and an I C Status and Control Register

(Figure 12-2). The I C Data Register is implemented as separate read and write registers. Generally, the I C Status and Control

Register should only be monitored after the I C interrupt, as all bits are valid at that time. Polling this register at other times could

read misleading bit status if a transaction is underway.

The I C clock (SCL) is connected to bit 0 of GPIO port 1, and the I C SDA data is connected to bit 1 GPIO port 1. The port

selection is determined by settings in the I C Port Configuration Register (Section 11.0). Once the I C-compatible functionality is

enabled by setting the I C Enable bit of the I C Status and Control Register (bit 0, Figure 12-2), the two LSB ([1:0]) of the

corresponding GPIO port is placed in Open Drain mode, regardless of the settings of the GPIO Configuration Register. In Open

Drain mode, the GPIO pin outputs LOW if the pin’s Data Register is ‘0’, and the pin is in Hi-Z mode if the pin’s Data Register is

‘1’. The electrical characteristics of the I C-compatible interface is the same as that of GPIO port 1. Note that the I (max) is 2

mA @ V = 2.0V for port 1.

All control of the I C clock (SCL) and data (SDA) lines is performed by the I C-compatible block.

I2C Data

Address 0x29

Bit #

Bit Name

Read/Write

Reset

I C Data 7

I C Data 6

I C Data 5

I C Data 4

R/W

I C Data 3

I C Data 2

I C Data 1

I C Data 0

R/W

Figure 12-1. I C Data Register

Bits [7..0]: I C Data

Contains the 8-bit data on the I C Bus.

I C Status and Control

Address 0x28

Bit #

Bit Name

MSTR Mode Continue/Bu Xmit Mode

ACK

Addr

ARB

Lost/Restart

Received

Stop

I C Enable

Read/Write

Reset

R/W

Figure 12-2. I C Status and Control Register

The I C Status and Control register bits are defined in Table 12-1, with a more detailed description following.

Table 12-1. I C Status and Control Register Bit Definitions

Bit

Name

Description

I C Enable

When set to ‘1’, the I C-compatible function is enabled. When cleared, I C GPIO pins operate

normally.

Received Stop

Reads 1 only in slave receive mode, when I C Stop bit detected (unless firmware did not ACK the

last transaction).

ARB Lost/Restart Reads 1 to indicate master has lost arbitration. Reads 0 otherwise.

Write to 1 in master mode to perform a restart sequence (also set Continue bit).

Addr

Reads 1 during first byte after start/restart in slave mode, or if master loses arbitration.

Reads 0 otherwise. This bit should always be written as 0.

ACK

In receive mode, write 1 to generate ACK, 0 for no ACK.

In transmit mode, reads 1 if ACK was received, 0 if no ACK received.

Xmit Mode

Write to 1 for transmit mode, 0 for receive mode.

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Table 12-1. I C Status and Control Register Bit Definitions (continued)

Bit

Name

Description

Write 1 to indicate ready for next transaction.

Reads 1 when I C-compatible block is busy with a transaction, 0 when transaction is complete.

Continue/Busy

MSTR Mode

Write to 1 for master mode, 0 for slave mode. This bit is cleared if master loses arbitration.

Clearing from 1 to 0 generates Stop bit.

Bit 7 : MSTR Mode

Setting this bit to 1 causes the I C-compatible block to initiate a master mode transaction by sending a start bit and

transmitting the first data byte from the data register (this typically holds the target address and R/W bit). Subsequent bytes

are initiated by setting the Continue bit, as described below.

Clearing this bit (set to 0) causes the GPIO pins to operate normally.

In master mode, the I C-compatible block generates the clock (SCK), and drives the data line as required depending on

transmit or receive state. The I C-compatible block performs any required arbitration and clock synchronization. IN the

event of a loss of arbitration, this MSTR bit is cleared, the ARB Lost bit is set, and an interrupt is generated by the

microcontroller. If the chip is the target of an external master that wins arbitration, then the interrupt is held off until the

transaction from the external master is completed.

When MSTR Mode is cleared from 1 to 0 by a firmware write, an I C Stop bit is generated.

Bit 6 : Continue/Busy

This bit is written by the firmware to indicate that the firmware is ready for the next byte transaction to begin. In other words,

the bit has responded to an interrupt request and has completed the required update or read of the data register. During a

read this bit indicates if the hardware is busy and is locking out additional writes to the I C Status and Control register. This

locking allows the hardware to complete certain operations that may require an extended period of time. Following an I C

interrupt, the I C-compatible block does not return to the Busy state until firmware sets the Continue bit. This allows the

firmware to make one control register write without the need to check the Busy bit.

Bit 5 : Xmit Mode

This bit is set by firmware to enter transmit mode and perform a data transmit in master or slave mode. Clearing this bit

sets the part in receive mode. Firmware generally determines the value of this bit from the R/W bit associated with the I C

address packet. The Xmit Mode bit state is ignored when initially writing the MSTR Mode or the Restart bits, as these cases

always cause transmit mode for the first byte.

Bit 4 : ACK

This bit is set or cleared by firmware during receive operation to indicate if the hardware should generate an ACK signal

on the I C-compatible bus. Writing a 1 to this bit generates an ACK (SDA LOW) on the I2C-compatible bus at the ACK bit

time. During transmits (Xmit Mode = 1), this bit should be cleared.

Bit 3 : Addr

This bit is set by the I C-compatible block during the first byte of a slave receive transaction, after an I C start or restart.

The Addr bit is cleared when the firmware sets the Continue bit. This bit allows the firmware to recognize when the master

has lost arbitration, and in slave mode it allows the firmware to recognize that a start or restart has occurred.

Bit 2 : ARB Lost/Restart

This bit is valid as a status bit (ARB Lost) after master mode transactions. In master mode, set this bit (along with the

Continue and MSTR Mode bits) to perform an I C restart sequence. The I C target address for the restart must be written

to the data register before setting the Continue bit. To prevent false ARB Lost signals, the Restart bit is cleared by hardware

during the restart sequence.

Bit 1 : Receive Stop

This bit is set when the slave is in receive mode and detects a stop bit on the bus. The Receive Stop bit is not set if the

firmware terminates the I C transaction by not acknowledging the previous byte transmitted on the I C-compatible bus,

e.g., in receive mode if firmware sets the Continue bit and clears the ACK bit.

Bit 0 : I C Enable

Set this bit to override GPIO definition with I C-compatible function on the two I C-compatible pins. When this bit is cleared,

these pins are free to function as GPIOs. In I C-compatible mode, the two pins operate in open drain mode, independent

of the GPIO configuration setting.

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13.0

Processor Status and Control Register

Processor Status and Control

Address 0xFF

Bit #

Bit Name

IRQ

Pending

Watchdog

Reset

USB Bus

Reset

Interrupt

Power-on

Reset

Suspend

Interrupt

Enable

Sense

Reserved

Run

Read/Write

Reset

R/W

Figure 13-1. Processor Status and Control Register

Bit 0: Run

This bit is manipulated by the HALT instruction. When Halt is executed, all the bits of the Processor Status and Control

Register are cleared to 0. Since the run bit is cleared, the processor stops at the end of the current instruction. The processor

remains halted until an appropriate reset occurs (power-on or Watchdog). This bit should normally be written as a ‘1.’

Bit 1: Reserved

Bit 1 is reserved and must be written as a zero.

Bit 2: Interrupt Enable Sense

This bit indicates whether interrupts are enabled or disabled. Firmware has no direct control over this bit as writing a zero

or one to this bit position has no effect on interrupts. A ‘0’ indicates that interrupts are masked off and a ‘1’ indicates that

the interrupts are enabled. This bit is further gated with the bit settings of the Global Interrupt Enable Register (Figure 14-1)

and USB End Point Interrupt Enable Register (Figure 14-2). Instructions DI, EI, and RETI manipulate the state of this bit.

Bit 3: Suspend

Writing a ‘1’ to the Suspend bit halts the processor and cause the microcontroller to enter the suspend mode that signifi-

cantly reduces power consumption. A pending, enabled interrupt or USB bus activity causes the device to come out of

suspend. After coming out of suspend, the device resumes firmware execution at the instruction following the IOWR which

put the part into suspend. An IOWR attempting to put the part into suspend is ignored if USB bus activity is present. See

Section 8.0 for more details on suspend mode operation.

Bit 4: Power-on Reset

The Power-on Reset is set to ‘1’ during a power-on reset. The firmware can check bits 4 and 6 in the reset handler to

determine whether a reset was caused by a power-on condition or a Watchdog timeout. A POR event may be followed by

a Watchdog reset before firmware begins executing, as explained below.

Bit 5: USB Bus Reset Interrupt

The USB Bus Reset Interrupt bit is set when the USB Bus Reset is detected on receiving a USB Bus Reset signal on the

upstream port. The USB Bus Reset signal is a single-ended zero (SE0) that lasts from 12 to 16 µs. An SE0 is defined as

the condition in which both the D+ line and the D– line are LOW at the same time.

Bit 6: Watchdog Reset

The Watchdog Reset is set during a reset initiated by the Watchdog Timer. This indicates the Watchdog Timer went for

more than t

(8 ms minimum) between Watchdog clears. This can occur with a POR event, as noted below.

WATCH

Bit 7: IRQ Pending

The IRQ pending, when set, indicates that one or more of the interrupts has been recognized as active. An interrupt remains

pending until its interrupt enable bit is set (Figure 14-1, Figure 14-2) and interrupts are globally enabled. At that point, the

internal interrupt handling sequence clears this bit until another interrupt is detected as pending.

During power-up, the Processor Status and Control Register is set to 00010001, which indicates a POR (bit 4 set) has occurred

and no interrupts are pending (bit 7 clear). During the 96-ms suspend at start-up (explained in Section 7.1), a Watchdog Reset

also occurs unless this suspend is aborted by an upstream SE0 before 8 ms. If a WDR occurs during the power-up suspend

interval, firmware reads 01010001 from the Status and Control Register after power-up. Normally, the POR bit should be cleared

so a subsequent WDR can be clearly identified. If an upstream bus reset is received before firmware examines this register, the

Bus Reset bit may also be set.

During a Watchdog Reset, the Processor Status and Control Register is set to 01XX0001, which indicates a Watchdog Reset (bit

6 set) has occurred and no interrupts are pending (bit 7 clear). The Watchdog Reset does not effect the state of the POR and the

Bus Reset Interrupt bits.

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14.0

Interrupts

Interrupts are generated by GPIO pins, internal timers, I C-compatible operation, internal USB hub and USB traffic conditions.

All interrupts are maskable by the Global Interrupt Enable Register and the USB End Point Interrupt Enable Register. Writing a

‘1’ to a bit position enables the interrupt associated with that bit position.

Global Interrupt Enable Register

Address 0X20

Bit #

Bit Name

Reserved I C Interrupt

Enable

GPIO

Interrupt

Enable

Reserved

USB Hub

Interrupt

Enable

1.024-ms

Interrupt

Enable

128-µs

Interrupt

Enable

USB Bus

RST

Interrupt

Enable

Read/Write

Reset

–

R/W

Figure 14-1. Global Interrupt Enable Register

Bit 0 : USB Bus RST Interrupt Enable

1 = Enable Interrupt on a USB Bus Reset; 0 = Disable interrupt on a USB Bus Reset (Refer to section 14.3).

Bit 1 :128-µs Interrupt Enable

1 = Enable Timer interrupt every 128 µs; 0 = Disable Timer Interrupt for every 128 µs.

Bit 2 : 1.024-ms Interrupt Enable

1 = Enable Timer interrupt every 1.024 ms; 0 = Disable Timer Interrupt every 1.024 ms.

Bit 3 : USB Hub Interrupt Enable

1 = Enable Interrupt on a Hub status change; 0 = Disable interrupt due to hub status change. (Refer to section 14.6.)

Bit 4 : Reserved.

Bit 5 : GPIO Interrupt Enable

1 = Enable Interrupt on falling/rising edge on any GPIO; 0 = Disable Interrupt on falling/rising edge on any GPIO (Refer to

section 14.7, 9 .1 and 9.2.).

Bit 6 : I C Interrupt Enable

1 = Enable Interrupt on I2C related activity; 0 = Disable I2C related activity interrupt. (Refer to section 14.8.)

Bit 7 : Reserved.

USB Endpoint Interrupt Enable

Address 0X21

Bit #

Bit Name

Reserved

EPB1

Interrupt

Enable

EPB0

Interrupt

Enable

EPA2

Interrupt

Enable

EPA1

Interrupt

Enable

EPA0

Interrupt

Enable

Read/Write

Reset

–

R/W

Figure 14-2. USB Endpoint Interrupt Enable Register

Bit 0: EPA0 Interrupt Enable

1 = Enable Interrupt on data activity through endpoint A0; 0 = Disable Interrupt on data activity through endpoint A0

Bit 1: EPA1 Interrupt Enable

1 = Enable Interrupt on data activity through endpoint A1; 0 = Disable Interrupt on data activity through endpoint A1

Bit 2: EPA2 Interrupt Enable

1 = Enable Interrupt on data activity through endpoint A2; 0 = Disable Interrupt on data activity through endpoint A2.

Bit 3: EPB0 Interrupt Enable

1 = Enable Interrupt on data activity through endpoint B0; 0 = Disable Interrupt on data activity through endpoint B0

Bit 4: EPB1 Interrupt Enable

1 = Enable Interrupt on data activity through endpoint B1; 0 = Disable Interrupt on data activity through endpoint B1

Bit [7..5] : Reserved

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During a reset, the contents of the Global Interrupt Enable Register and USB End Point Interrupt Enable Register are cleared,

effectively disabling all interrupts,

The interrupt controller contains a separate flip-flop for each interrupt. See Figure 14-3 for the logic block diagram of the interrupt

controller. When an interrupt is generated, it is first registered as a pending interrupt. It stays pending until it is serviced or a reset

occurs. A pending interrupt only generates an interrupt request if it is enabled by the corresponding bit in the interrupt enable

registers. The highest priority interrupt request is serviced following the completion of the currently executing instruction.

When servicing an interrupt, the hardware does the following:

1. Disables all interrupts by clearing the Global Interrupt Enable bit in the CPU (the state of this bit can be read at Bit 2 of the

Processor Status and Control Register, Figure 13-1).

2. Clears the flip-flop of the current interrupt.

3. Generates an automatic CALL instruction to the ROM address associated with the interrupt being serviced (i.e., the Interrupt

Vector, see Section 14.1).

The instruction in the interrupt table is typically a JMP instruction to the address of the Interrupt Service Routine (ISR). The user

can reenable interrupts in the interrupt service routine by executing an EI instruction. Interrupts can be nested to a level limited

only by the available stack space.

The Program Counter value as well as the Carry and Zero flags (CF, ZF) are stored onto the Program Stack by the automatic

CALL instruction generated as part of the interrupt acknowledge process. The user firmware is responsible for ensuring that the

processor state is preserved and restored during an interrupt. The PUSH A instruction should typically be used as the first

command in the ISR to save the accumulator value and the POP A instruction should be used to restore the accumulator value

just before the RETI instruction. The program counters CF and ZF are restored and interrupts are enabled when the RETI

instruction is executed.

The IDI and EI instruction can be used to disable and enable interrupts, respectively. These instruction affect only the Global

Interrupt Enable bit of the CPU. If desired, EI can be used to re-enable interrupts while inside an ISR, instead of waiting for the

RETI that exits the ISR. While the global interrupt enable bit is cleared, the presence of a pending interrupt can be detected by

examining the IRQ Sense bit (Bit 7 in the Processor Status and Control Register).

14.1

Interrupt Vectors

The Interrupt Vectors supported by the USB Controller are listed in Table 14-1. The lowest-numbered interrupt (USB Bus Reset

interrupt) has the highest priority, and the highest-numbered interrupt (I C interrupt) has the lowest priority.

USB Reset Clear

Interrupt

Vector

To CPU

CLR

USB Reset IRQ

128-µs CLR

128-µs IRQ

1-ms CLR

1-ms IRQ

Enable [0]

(Reg 0x20)

CPU

USB Reset Int

IRQ Sense

IRQ

CLK

IRQout

AddrA EP0 CLR

AddrA EP0 IRQ

AddrA EP1 CLR

AddrA EP1 IRQ

AddrA EP2 CLR

AddrA EP2 IRQ

CLR

Global

Interrupt

Enable

Bit

Int Enable

Sense

Enable [2]

(Reg 0x21)

AddrB EP0 CLR

AddrB EP0 IRQ

AddrA ENP2 Int

CLK

AddrB EP1 CLR

AddrB EP1 IRQ

Controlled by DI, EI, and

RETI Instructions

CLR

Hub CLR

Hub IRQ

Interrupt

Acknowledge

DAC CLR

DAC IRQ

GPIO CLR

GPIO IRQ

I²C CLR

CLR

I²C IRQ

Enable [6]

(Reg 0x20)

Interrupt Priority Encoder

I²C Int

CLK

Figure 14-3. Interrupt Controller Function Diagram

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Although Reset is not an interrupt, the first instruction executed after a reset is at PROM address 0x0000h—which corresponds

to the first entry in the Interrupt Vector Table. Because the JMP instruction is two bytes long, the interrupt vectors occupy two bytes.

Table 14-1. Interrupt Vector Assignments

Interrupt Vector Number

ROM Address

0x0000

0x0002

0x0004

0x0006

0x0008

0x000A

0x000C

0x000E

0x0010

0x0012

0x0014

0x0016

0x0018

Function

Execution after Reset begins here

USB Bus Reset interrupt

Not Applicable

128-µs timer interrupt

1.024-ms timer interrupt

USB Address A Endpoint 0 interrupt

USB Address A Endpoint 1 interrupt

USB Address A Endpoint 2 interrupt

USB Address B Endpoint 0 interrupt

USB Address B Endpoint 1 interrupt

USB Hub interrupt

DAC interrupt

GPIO interrupt

I C interrupt

14.2

Interrupt Latency

Interrupt latency can be calculated from the following equation:

Interrupt latency = (Number of clock cycles remaining in the current instruction) + (10 clock cycles for the CALL instruction) +

(5 clock cycles for the JMP instruction)

For example, if a 5-clock cycle instruction such as JC is being executed when an interrupt occurs, the first instruction of the

Interrupt Service Routine executes a minimum of 16 clocks (1+10+5) or a maximum of 20 clocks (5+10+5) after the interrupt is

issued. For a 12-MHz internal clock (6-MHz crystal), 20 clock periods is 20/12 MHz = 1.667 µs.

14.3

USB Bus Reset Interrupt

The USB Controller recognizes a USB Reset when a Single Ended Zero (SE0) condition persists on the upstream USB port for

12–16 µs. SE0 is defined as the condition in which both the D+ line and the D– line are LOW. A USB Bus Reset may be recognized

for an SE0 as short as 12 µs, but is always recognized for an SE0 longer than 16 µs. When a USB Bus Reset is detected, bit 5

of the Processor Status and Control Register (Figure 13-1) is set to record this event. In addition, the controller clears the following

registers:

SIE Section: .... USB Device Address Registers (0x10, 0x40)

Hub Section: ......................Hub Ports Connect Status (0x48)

........................................................Hub Ports Enable (0x49)

........................................................ Hub Ports Speed (0x4A)

.................................................... Hub Ports Suspend (0x4D)

.......................................... Hub Ports Resume Status (0x4E)

.................................................Hub Ports SE0 Status (0x4F)

........................................................... Hub Ports Data (0x50)

.............................................Hub Downstream Force (0x51).

A USB Bus Reset Interrupt is generated at the end of the USB Bus Reset condition when the SE0 state is deasserted. If the USB

reset occurs during the start-up delay following a POR, the delay is aborted as described in Section 7.1.

14.4

Timer Interrupt

There are two periodic timer interrupts: the 128-µs interrupt and the 1.024-ms interrupt. The user should disable both timer

interrupts before going into the suspend mode to avoid possible conflicts between servicing the timer interrupts first or the suspend

request first.

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14.5

USB Endpoint Interrupts

There are five USB endpoint interrupts, one per endpoint. A USB endpoint interrupt is generated after the USB host writes to a

USB endpoint FIFO or after the USB controller sends a packet to the USB host. The interrupt is generated on the last packet of

the transaction (e.g., on the host’s ACK on an IN transfer, or on the device ACK on an OUT transfer). If no ACK is received during

an IN transaction, no interrupt is generated.

14.6

USB Hub Interrupt

A USB hub interrupt is generated by the hardware after a connect/disconnect change, babble, or a resume event is detected by

the USB repeater hardware. The babble and resume events are additionally gated by the corresponding bits of the Hub Port

Enable Register (Figure 16-3). The connect/disconnect event on a port does not generate an interrupt if the SIE does not drive

the port (i.e., the port is being forced).

14.7

GPIO Interrupt

Each of the GPIO pins can generate an interrupt, if enabled. The interrupt polarity can be programmed for each GPIO port as

part of the GPIO configuration. All of the GPIO pins share a single interrupt vector, which means the firmware needs to read the

GPIO ports with enabled interrupts to determine which pin or pins caused an interrupt. A block diagram of the GPIO interrupt

logic is shown in Figure 14-4.

Port

Configuration

GPIO Interrupt

Flip Flop

OR Gate

(1 input per

GPIO pin)

IRQout

Interrupt

Priority

Interrupt

Vector

Encoder

GPIO

CLR

Port Interrupt

Enable Register

1 = Enable

0 = Disable

IRA

Global

GPIO Interrupt

Enable

1 = Enable

0 = Disable

(Bit 5, Register 0x20)

Figure 14-4. GPIO Interrupt Structure

Refer to Sections 9.1 and 9.2 for more information of setting GPIO interrupt polarity and enabling individual GPIO interrupts. If

one port pin has triggered an interrupt, no other port pins can cause a GPIO interrupt until that port pin has returned to its inactive

(non-trigger) state or its corresponding port interrupt enable bit is cleared. The USB Controller does not assign interrupt priority

to different port pins and the Port Interrupt Enable Registers are not cleared during the interrupt acknowledge process.

14.8

I C Interrupt

The I C interrupt occurs after various events on the I C-compatible bus to signal the need for firmware interaction. This generally

involves reading the I C Status and Control Register (Figure 12-2) to determine the cause of the interrupt, loading/reading the

I C Data Register as appropriate, and finally writing the Processor Status and Control Register (Figure 13-1) to initiate the

subsequent transaction. The interrupt indicates that status bits are stable and it is safe to read and write the I C registers. Refer

to Section 12.0 for details on the I C registers.

When enabled, the I C-compatible state machines generate interrupts on completion of the following conditions. The referenced

bits are in the I C Status and Control Register.

1. In slave receive mode, after the slave receives a byte of data: The Addr bit is set, if this is the first byte since a start or restart

signal was sent by the external master. Firmware must read or write the data register as necessary, then set the ACK, Xmit

MODE, and Continue/Busy bits appropriately for the next byte.

2. In slave receive mode, after a stop bit is detected: The Received Stop bit is set, if the stop bit follows a slave receive transaction

where the ACK bit was cleared to 0, no stop bit detection occurs.

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3. In slave transmit mode, after the slave transmits a byte of data: The ACK bit indicates if the master that requested the byte

acknowledged the byte. If more bytes are to be sent, firmware writes the next byte into the Data Register and then sets the

Xmit MODE and Continue/Busy bits as required.

4. In master transmit mode, after the master sends a byte of data. Firmware should load the Data Register if necessary, and

set the Xmit MODE, MSTR MODE, and Continue/Busy bits appropriately. Clearing the MSTR MODE bit issues a stop signal

to the I C-compatible bus and return to the idle state.

5. In master receive mode, after the master receives a byte of data: Firmware should read the data and set the ACK and

Continue/Busy bits appropriately for the next byte. Clearing the MSTR MODE bit at the same time causes the master state

machine to issue a stop signal to the I C-compatible bus and leave the I2C-compatible hardware in the idle state.

6. When the master loses arbitration: This condition clears the MSTR MODE bit and sets the ARB Lost/Restart bit immediately

and then waits for a stop signal on the I C-compatible bus to generate the interrupt.

The Continue/Busy bit is cleared by hardware prior to interrupt conditions 1 to 4. Once the Data Register has been read or written,

firmware should configure the other control bits and set the Continue/Busy bit for subsequent transactions. Following an interrupt

from master mode, firmware should perform only one write to the Status and Control Register that sets the Continue/Busy bit,

without checking the value of the Continue/Busy bit. The Busy bit may otherwise be active and I C register contents may be

changed by the hardware during the transaction, until the I C interrupt occurs.

15.0

USB Overview

The USB hardware includes a USB Hub repeater with one upstream and up to seven downstream ports. The USB Hub repeater

interfaces to the microcontroller through a full-speed serial interface engine (SIE). An external series resistor of R must be

ext

placed in series with all upstream and downstream USB outputs in order to meet the USB driver requirements of the USB

specification. The CY7C65113C microcontroller can provide the functionality of a compound device consisting of a USB hub and

permanently attached functions.

15.1

USB Serial Interface Engine (SIE)

The SIE allows the CY7C65113C microcontroller to communicate with the USB host through the USB repeater portion of the hub.

The SIE simplifies the interface between the microcontroller and USB by incorporating hardware that handles the following USB

bus activity independently of the microcontroller:

• Bit stuffing/unstuffing

• Checksum generation/checking

• ACK/NAK/STALL

• Token type identification

• Address checking.

Firmware is required to handle the following USB interface tasks:

• Coordinate enumeration by responding to SETUP packets

• Fill and empty the FIFOs

• Suspend/Resume coordination

• Verify and select DATA toggle values.

15.2

USB Enumeration

The internal hub and any compound device function are enumerated under firmware control. The hub is enumerated first, followed

by any integrated compound function. After the hub is enumerated, the USB host can read hub connection status to determine

which (if any) of the downstream ports need to be enumerated. The following is a brief summary of the typical enumeration

process of the CY7C65113C by the USB host. For a detailed description of the enumeration process, refer to the USB specifi-

cation.

In this description, ‘Firmware’ refers to embedded firmware in the CY7C65113C controller.

1. The host computer sends a SETUP packet followed by a DATA packet to USB address 0 requesting the Device descriptor.

2. Firmware decodes the request and retrieves its Device descriptor from the program memory tables.

3. The host computer performs a control read sequence and Firmware responds by sending the Device descriptor over the USB

bus, via the on-chip FIFOs.

4. After receiving the descriptor, the host sends a SETUP packet followed by a DATA packet to address 0 assigning a new USB

address to the device.

5. Firmware stores the new address in its USB Device Address Register (for example, as Address B) after the no-data control

sequence completes.

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6. The host sends a request for the Device descriptor using the new USB address.

7. Firmware decodes the request and retrieves the Device descriptor from program memory tables.

8. The host performs a control read sequence and Firmware responds by sending its Device descriptor over the USB bus.

9. The host generates control reads from the device to request the Configuration and Report descriptors.

10.Once the device receives a Set Configuration request, its functions may now be used.

11.Following enumeration as a hub, Firmware can optionally indicate to the host that a compound device exists (for example, the

keyboard in a keyboard/hub device).

12.The host carries out the enumeration process with this additional function as though it were attached downstream from the hub.

13.When the host assigns an address to this device, it is stored as the other USB address (for example, Address A).

16.0

USB Hub

A USB hub is required to support:

• Connectivity behavior: service connect/disconnect detection

• Bus fault detection and recovery

• Full-/Low-speed device support

These features are mapped onto a hub repeater and a hub controller. The hub controller is supported by the processor integrated

into the CY7C65113C microcontroller. The hardware in the hub repeater detects whether a USB device is connected to a

downstream port. The connection to a downstream port is through a differential signal pair (D+ and D–). Each downstream port

provided by the hub requires external R

resistors from each signal line to ground, so that when a downstream port has no

UDN

device connected, the hub reads a LOW (zero) on both D+ and D–. This condition is used to identify the “no connect” state.

The hub must have a resistor R connected between its upstream D+ line and V to indicate it is a full speed USB device.

UUP

REG

The hub generates an EOP at EOF1, in accordance with the USB 1.1 Specification (section 11.2.2, page 234) as well as USB

2.0 specification (section 11.2.5, page 304).

16.1

Connecting/Disconnecting a USB Device

A low-speed (1.5 Mbps) USB device has a pull-up resistor on the D– pin. At connect time, the bias resistors set the signal levels

on the D+ and D– lines. When a low-speed device is connected to a hub port, the hub sees a LOW on D+ and a HIGH on D–.

This causes the hub repeater to set a connect bit in the Hub Ports Connect Status register for the downstream port (see

Figure 16-1). Then the hub repeater generates a Hub Interrupt to notify the microcontroller that there has been a change in the

Hub downstream status. The firmware sets the speed of this port in the Hub Ports Speed Register (see Figure 16-2).

A full-speed (12 Mbps) USB device has a pull-up resistor from the D+ pin, so the hub sees a HIGH on D+ and a LOW on D–. In

this case, the hub repeater sets a connect bit in the Hub Ports Connect Status register and generates a Hub Interrupt to notify

the microcontroller of the change in Hub status. The firmware sets the speed of this port in the Hub Ports Speed Register (see

Figure 16-2)

Connects are recorded by the time a non-SE0 state lasts for more than 2.5 µs on a downstream port.

When a USB device is disconnected from the Hub, the downstream signal pair eventually floats to a single-ended zero state. The

hub repeater recognizes a disconnect once the SE0 state on a downstream port lasts from 2.0 to 2.5 µs. On a disconnect, the

corresponding bit in the Hub Ports Connect Status register is cleared, and the Hub Interrupt is generated

Hub Ports Connect Status

Address 0x48

Bit #

Bit Name

Reserved

Port 4

Connect

Status

Port 3

Connect

Status

Port 2

Connect

Status

Port 1

Connect

Status

Read/Write

Reset

R/W

Figure 16-1. Hub Ports Connect Status

Bit [0..3] : Port x Connect Status (where x = 1..4).

When set to 1, Port x is connected; When set to 0, Port x is disconnected.

Bit [4..7] : Reserved.

Set to 0.

The Hub Ports Connect Status register is cleared to zero by reset or USB bus reset, then set to match the hardware configuration

by the hub repeater hardware. The Reserved bits [4..7] should always read as ‘0’ to indicate no connection.

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Hub Ports Speed

Address 0x4A

Bit #

Reserved

R/W

Reserved

R/W

Bit Name

Read/Write

Reset

Reserved

Reserved Port 4 Speed Port 3 Speed Port 2 Speed Port 1 Speed

R/W

Figure 16-2. Hub Ports Speed

Bit [0..3] : Port x Speed (where x = 1..4).

Set to 1 if the device plugged in to Port x is Low Speed; Set to 0 if the device plugged in to Port x is Full Speed.

Bit [4..7] : Reserved.

Set to 0.

The Hub Ports Speed register is cleared to zero by reset or bus reset. This must be set by the firmware on issuing a port reset.

The Reserved bits [4..7] should always read as ‘0.’

16.2

Enabling/Disabling a USB Device

After a USB device connection has been detected, firmware must update status change bits in the hub status change data

structure that is polled periodically by the USB host. The host responds by sending a packet that instructs the hub to reset and

enable the downstream port. Firmware then sets the bit in the Hub Ports Enable register (Figure 16-3), for the downstream port.

The hub repeater hardware responds to an enable bit in the Hub Ports Enable register (Figure 16-3) by enabling the downstream

port, so that USB traffic can flow to and from that port.

If a port is marked enabled and is not suspended, it receives all USB traffic from the upstream port, and USB traffic from the

downstream port is passed to the upstream port (unless babble is detected). Low-speed ports do not receive full-speed traffic

from the upstream port.

When firmware writes to the Hub Ports Enable register (Figure 16-3) to enable a port, the port is not enabled until the end of any

packet currently being transmitted. If there is no USB traffic, the port is enabled immediately.

When a USB device disconnection has been detected, firmware must update status bits in the hub change status data structure

that is polled periodically by the USB host. In suspended mode, a connect or disconnect event generates an interrupt (if the hub

interrupt is enabled) even if the port is disabled.

Hub Ports Enable Register

Address 0x49

Bit #

Reserved

R/W

Reserved

R/W

Reserved

R/W

Bit Name

Read/Write

Reset

Reserved Port 4 Enable Port 3 Enable Port 2 Enable Port 1 Enable

R/W

Figure 16-3. Hub Ports Enable Register

Bit [0..3] : Port x Enable (where x = 1..4)

Set to 1 if Port x is enabled; Set to 0 if Port x is disabled

Bit [4..7] : Reserved.

Set to 0.

The Hub Ports Enable register is cleared to zero by reset or bus reset to disable all downstream ports as the default condition.

A port is also disabled by internal hub hardware (enable bit cleared) if babble is detected on that downstream port. Babble is

defined as:

• Any non-idle downstream traffic on an enabled downstream port at EOF2.

• Any downstream port with upstream connectivity established at EOF2 (i.e., no EOP received by EOF2).

16.3

Hub Downstream Ports Status and Control

Data transfer on hub downstream ports is controlled according to the bit settings of the Hub Downstream Ports Control Register

(Figure 16-4). Each downstream port is controlled by two bits, as defined in Table 16-1 below. The Hub Downstream Ports Control

Register is cleared upon reset or bus reset, and the reset state is the state for normal USB traffic. Any downstream port being

forced must be marked as disabled (Figure 16-3) for proper operation of the hub repeater.

Firmware should use this register for driving bus reset and resume signaling to downstream ports. Controlling the port pins through

this register uses standard USB edge rate control according to the speed of the port, set in the Hub Port Speed Register.

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The downstream USB ports are designed for connection of USB devices, but can also serve as output ports under firmware

control. This allows unused USB ports to be used for functions such as driving LEDs or providing additional input signals. Pulling

up these pins to voltages above V

may cause current flow into the pin.

REF

This register is not reset by USB bus reset. These bits must be cleared before going into suspend.

Hub Downstream Ports Control Register

Address 0x4B

Bit #

Bit Name

Port 4

Port 3

Port 2

Port 1

Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0

Read/Write

Reset

R/W

Figure 16-4. Hub Downstream Ports Control Register

Table 16-1. Control Bit Definition for Downstream Ports

Control Bits

Bit1

Bit 0

Control Action

Not Forcing (Normal USB Function)

Force Differential ‘1’ (D+ HIGH, D– LOW)

Force Differential ‘0’ (D+ LOW, D– HIGH)

Force SE0 state

An alternate means of forcing the downstream ports is through the Hub Ports Force Low Register (Figure 16-5) Register. With

this register the pins of the downstream ports can be individually forced LOW, or left unforced. Unlike the Hub Downstream Ports

Control Register, above, the Force Low Register does not produce standard USB edge rate control on the forced pins. However,

this register allows downstream port pins to be held LOW in suspend. This register can be used to drive SE0 on all downstream

ports when unconfigured, as required in the USB 1.1 specification.

Hub Ports Force Low

Address 0x51

Bit #

Bit Name

Force Low

D+[4]

Force Low

D–[4]

Force Low

D+[3]

Force Low

D–[3]

Force Low

D+[2]

Force Low

D–[2]

Force Low

D+[1]

Force Low

D–[1]

Read/Write

Reset

R/W

Figure 16-5. Hub Ports Force Low Register

The data state of downstream ports can be read through the HUB Ports SE0 Status Register (Figure 16-6) and the Hub Ports

Data Register (Figure 16-7). The data read from the Hub Ports Data Register is the differential data only and is independent of

the settings of the Hub Ports Speed Register (Figure 16-2). When the SE0 condition is sensed on a downstream port, the

corresponding bits of the Hub Ports Data Register hold the last differential data state before the SE0. Hub Ports SE0 Status

Hub Ports SE0 Status

Address 0x4F

Bit #

Bit Name

Reserved

Port 4

Port 3

Port 2

Port 1

SE0 Status SE0 Status SE0 Status SE0 Status

Read/Write

Reset

Figure 16-6. Hub Ports SE0 Status Register

Bit [0..3]: Port x SE0 Status (where x = 1..4).

Set to 1 if a SE0 is output on the Port x bus; Set to 0 if a Non-SE0 is output on the Port x bus.

Bit [4..7]: Reserved.

Set to 0

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Hub Ports Data

ADDRESS 0x50

Bit #

Bit Name

Reserved

Port 4 Diff.

Data

Port 3 Diff.

Data

Port 2 Diff.

Data

Port 1 Diff.

Data

Read/Write

Reset

Figure 16-7. Hub Ports Data Register

Bit [0..3] : Port x Diff Data (where x = 1..4).

Set to 1 if D+ > D- (forced differential 1, if signal is differential, i.e. not a SE0 or SE1). Set to 0 if D- > D+ (forced differential

0, if signal is differential, i.e. not a SE0 or SE1).

Bit [4..7] : Reserved.

Set to 0.

16.4

Downstream Port Suspend and Resume

The Hub Ports Suspend Register (Figure 16-8) and Hub Ports Resume Status Register (Figure 16-9) indicate the suspend and

resume conditions on downstream ports. The suspend register must be set by firmware for any ports that are selectively

suspended. Also, this register is only valid for ports that are selectively suspended.

If a port is marked as selectively suspended, normal USB traffic is not sent to that port. Resume traffic is also prevented from

going to that port, unless the Resume comes from the selectively suspended port. If a resume condition is detected on the port,

hardware reflects a Resume back to the port, sets the Resume bit in the Hub Ports Resume Register, and generates a hub

interrupt.

If a disconnect occurs on a port marked as selectively suspended, the suspend bit is cleared.

The Device Remote Wakeup bit (bit 7) of the Hub Ports Suspend Register controls whether or not the resume signal is propagated

by the hub after a connect or a disconnect event. If the Device Remote Wakeup bit is set, the hub will automatically propagate

the resume signal after a connect or a disconnect event. If the Device Remote Wakeup bit is cleared, the hub will not propagate

the resume signal. The setting of the Device Remote Wakeup flag has no impact on the propagation of the resume signal after

a downstream remote wakeup event. The hub will automatically propagate the resume signal after a remote wakeup event,

regardless of the state of the Device Remote wakeup bit. The state of this bit has no impact on the generation of the hub interrupt.

A resume bit is set automatically when hardware detects a resume condition on a selectively suspended downstream port. The

resume condition is a differential ‘1’ for a low-speed device and a differential ‘0’ for a full-speed device.

These registers are cleared on reset or USB bus reset.

Hub Ports Suspend

Address 0x4D

Bit #

Bit Name

Device

Remote

Wakeup

Reserved

Port 4

Selective

Suspend

Port 3

Selective

Suspend

Port 2

Selective

Suspend

Port 1

Selective

Suspend

Read/Write

Reset

R/W

Figure 16-8. Hub Ports Suspend Register

Bit [0..3] : Port x Selective Suspend (where x = 1..4).

Set to 1 if Port x is Selectively Suspended; Set to 0 if Port x Do not suspend.

Bit 7 : Device Remote Wakeup.

When set to 1, Enable hardware upstream resume signaling for connect/disconnect events during global resume.

When set to 0, Disable hardware upstream resume signaling for connect/disconnect events during global resume.

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Hub Ports Resume

Address 0x4E

Bit #

Bit Name

Read/Write

Reset

Reserved

Resume 4

Resume 3

Resume 2

Resume 1

Figure 16-9. Hub Ports Resume Status Register

Bit [0..3] : Resume x (where x = 1..4).

When set to 1 Port x requesting to be resumed (set by hardware); default state is 0.

Bit [4..7] : Reserved.

Set to 0.

Resume from a selectively suspended port, with the hub not in suspend, typically involves the following actions:

1. Hardware detects the Resume, drives a K to the port, and generates the hub interrupt. The corresponding bit in the Resume

Status Register (0x4E) reads ‘1’ in this case.

2. Firmware responds to hub interrupt, and reads register 0x4E to determine the source of the Resume.

3. Firmware begins driving K on the port for 10 ms or more through register 0x4B.

4. Firmware clears the Selective Suspend bit for the port (0x4D), which clears the Resume bit (0x4E). This ends the hardware-driv-

en Resume, but the firmware-driven Resume continues. To prevent traffic being fed by the hub repeater to the port during or

just after the Resume, firmware should disable this port.

5. Firmware drives a timed SE0 on the port for two low-speed bit times as appropriate. Firmware must disable interrupts during

this SE0 so the SE0 pulse isn’t inadvertently lengthened, and appear as a bus reset to the downstream device.

6. Firmware drives a J on the port for one low-speed bit time, then it idles the port.

7. Firmware re-enables the port.

Resume when the hub is suspended typically involves these actions:

1. Hardware detects the Resume, drives a K on the upstream (which is then reflected to all downstream enabled ports), and

generates the hub interrupt.

2. The part comes out of suspend and the clocks start.

3. Once the clocks are stable, firmware execution resumes. An internal counter ensures that this takes at least 1 ms. Firmware

should check for Resume from any selectively suspended ports. If found, the Selective Suspend bit for the port should be

cleared; no other action is necessary.

4. The Resume ends when the host stops sending K from upstream. Firmware should check for changes to the Enable and

Connect Registers. If a port has become disabled but is still connected, an SE0 has been detected on the port. The port should

be treated as having been reset, and should be reported to the host as newly connected.

Firmware can choose to clear the Device Remote Wake-up bit (if set) to implement firmware timed states for port changes. All

allowed port changes wake the part. Then, the part can use internal timing to determine whether to take action or return to

suspend. If Device Remote Wake-up is set, automatic hardware assertions take place on Resume events.

16.5

USB Upstream Port Status and Control

USB status and control is regulated by the USB Status and Control Register, as shown in Figure 16-10. All bits in the register are

cleared during reset.

USB Status and Control

Address 0x1F

Bit #

Bit Name

Endpoint

Size

Endpoint

Mode

D+

Upstream

D–

Upstream

Bus Activity

Control

Action

Bit 2

Control

Action

Bit 1

Control

Action

Bit 0

Read/Write

Reset

R/W

Figure 16-10. USB Status and Control Register

Bits[2..0]: Control Action

Set to control action as per Table 16-2. The three control bits allow the upstream port to be driven manually by firmware.

For normal USB operation, all of these bits must be cleared. Table 16-2 shows how the control bits affect the upstream port.

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Table 16-2. Control Bit Definition for Upstream Port

Control Bits

000

Control Action

Not Forcing (SIE Controls Driver)

Force D+[0] HIGH, D–[0] LOW

Force D+[0] LOW, D–[0] HIGH

Force SE0; D+[0] LOW, D–[0] LOW

Force D+[0] LOW, D–[0] LOW

Force D+[0] HiZ, D–[0] LOW

Force D+[0] LOW, D–[0] HiZ

Force D+[0] HiZ, D–[0] HiZ

001

010

011

100

101

110

111

Bit 3: Bus Activity.

This is a “sticky” bit that indicates if any non-idle USB event has occurred on the upstream USB port. Firmware should

check and clear this bit periodically to detect any loss of bus activity. Writing a ‘0’ to the Bus Activity bit clears it, while writing

a ‘1’ preserves the current value. In other words, the firmware can clear the Bus Activity bit, but only the SIE can set it.

Bits 4 and 5: D– Upstream and D+ Upstream.

These bits give the state of each upstream port pin individually: 1 = HIGH, 0 = LOW.

Bit 6: Endpoint Mode.

This bit used to configure the number of USB endpoints. See Section 17.2 for a detailed description.

Bit 7: Endpoint Size.

This bit used to configure the number of USB endpoints. See Section 17.2 for a detailed description.

The hub generates an EOP at EOF1 in accordance with the USB 1.1 Specification, Section 11.2.2 as well as USB 2.0 specification

(section 11.2.5, page 304).

17.0

USB Serial Interface Engine Operation

The CY7C65113C SIE supports operation as a single device or a compound device. This section describes the two device

addresses, the configurable endpoints, and the endpoint function.

17.1

USB Device Addresses

The USB Controller provides two USB Device Address Registers: A (addressed at 0x10)and B (addressed at 0x40). Upon reset

and under default conditions, Device A has three endpoints and Device B has two endpoints. The USB Device Address Register

contents are cleared during a reset, setting the USB device addresses to zero and disabling these addresses. Figure 17-1 shows

the format of the USB Address Registers.

USB Device Address (Device A, B)

Addresses 0x10(A) and 0x40(B)

Bit #

Bit Name

Device

Address

Enable

Device

Address

Bit 6

Device

Address

Bit 5

Device

Address

Bit 4

Device

Address

Bit 3

Device

Address

Bit 2

Device

Address

Bit 1

Device

Address

Bit 0

Read/Write

Reset

R/W

Figure 17-1. USB Device Address Registers

Bits[6..0]: Device Address.

Firmware writes this bits during the USB enumeration process to the non-zero address assigned by the USB host.

Bit 7: Device Address Enable.

Must be set by firmware before the SIE can respond to USB traffic to the Device Address.

17.2

USB Device Endpoints

The CY7C65113C controller supports up to two addresses and five endpoints for communication with the host. The configuration

of these endpoints, and associated FIFOs, is controlled by bits [7,6] of the USB Status and Control Register (Figure 16-10). Bit

7 controls the size of the endpoints and bit 6 controls the number of addresses. These configuration options are detailed in

Table 17-1. Endpoint FIFOs are part of user RAM (as shown in Section 5.4.1).

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Table 17-1. Memory Allocation for Endpoints

USB Status And Control Register (0x1F) Bits [7, 6]

[0,0]

[1,0]

[0,1]

[1,1]

Two USB Addresses:

A (3 Endpoints) and

B (2 Endpoints)

Two USB Addresses:

A (3 Endpoints) and

B (2 Endpoints)

One USB Address:

A (5 Endpoints)

One USB Address:

A (5 Endpoints)

Label Start Address Size Label Start Address Size Label Start Address Size Label Start Address Size

EPB1

EPB0

EPA2

EPA1

EPA0

0xD8

0xE0

0xE8

0xF0

0xF8

EPB0

EPB1

EPA0

EPA1

EPA2

0xA8

0xB0

0xB8

0xC0

0xE0

EPA4

EPA3

EPA2

EPA1

EPA0

0xD8

0xE0

0xE8

0xF0

0xF8

EPA3

EPA4

EPA0

EPA1

EPA2

0xA8

0xB0

0xB8

0xC0

0xE0

When the SIE writes data to a FIFO, the internal data bus is driven by the SIE; not the CPU. This causes a short delay in the

CPU operation. The delay is three clock cycles per byte. For example, an 8-byte data write by the SIE to the FIFO generates a

delay of 2 µs (3 cycles/byte * 83.33 ns/cycle * 8 bytes).

17.3

USB Control Endpoint Mode Registers

All USB devices are required to have a control endpoint 0 (EPA0 and EPB0) that is used to initialize and control each USB address.

Endpoint 0 provides access to the device configuration information and allows generic USB status and control accesses. Endpoint

0 is bidirectional to both receive and transmit data. The other endpoints are unidirectional, but selectable by the user as IN or

OUT endpoints.

The endpoint mode registers are cleared during reset. When USB Status And Control Register Bits [6,7] are set to [0,0] or [1,0],

the endpoint zero EPA0 and EPB0 mode registers use the format shown in Figure 17-2.

USB Device Endpoint Zero Mode (A0, B0)

Addresses 0x12(A0) and 0x42(B0)

Bit #

Bit Name

Endpoint 0

SETUP

Endpoint 0 Endpoint 0

ACK

Mode Bit 3 Mode Bit 2 Mode Bit 1 Mode Bit 0

OUT

Received

Read/Write

Reset

R/W

Figure 17-2. USB Device Endpoint Zero Mode Registers

Bits[3..0]: Mode.

These sets the mode which control how the control endpoint responds to traffic.

Bit 4: ACK.

This bit is set whenever the SIE engages in a transaction to the register’s endpoint that completes with an ACK packet.

Bit 5: Endpoint 0 OUT Received.

1 = Token received is an OUT token. 0 = Token received is not an OUT token. This bit is set by the SIE to report the type

of token received by the corresponding device address is an OUT token. The bit must be cleared by firmware as part of

the USB processing.

Bit 6: Endpoint 0 IN Received.

1 = Token received is an IN token. 0 = Token received is not an IN token. This bit is set by the SIE to report the type of

token received by the corresponding device address is an IN token. The bit must be cleared by firmware as part of the USB

processing.

Bit 7: Endpoint 0 SETUP Received.

1 = Token received is a SETUP token. 0 = Token received is not a SETUP token. This bit is set ONLY by the SIE to report

the type of token received by the corresponding device address is a SETUP token. Any write to this bit by the CPU will

clear it (set it to 0). The bit is forced HIGH from the start of the data packet phase of the SETUP transaction until the start

of the ACK packet returned by the SIE. The CPU should not clear this bit during this interval, and subsequently, until the

CPU first does an IORD to this endpoint 0 mode register. The bit must be cleared by firmware as part of the USB

[4]

processing.

Note:

4. In 5-endpoint mode (USB Status And Control Register Bits [7,6] are set to [0,1] or [1,1]), Register 0x42 serves as non-control endpoint 3, and has the format for

non-control endpoints shown in Figure 17-3.

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Bits[6:0] of the endpoint 0 mode register are locked from CPU write operations whenever the SIE has updated one of these bits,

which the SIE does only at the end of the token phase of a transaction (SETUP... Data... ACK, OUT... Data... ACK, or IN... Data...

ACK). The CPU can unlock these bits by doing a subsequent read of this register. Only endpoint 0 mode registers are locked

when updated. The locking mechanism does not apply to the mode registers of other endpoints.

Because of these hardware locking features, firmware must perform an IORD after an IOWR to an endpoint 0 register. This verifies

that the contents have changed as desired, and that the SIE has not updated these values.

While the SETUP bit is set, the CPU cannot write to the endpoint zero FIFOs. This prevents firmware from overwriting an incoming

SETUP transaction before firmware has a chance to read the SETUP data. Refer to T a ble 17-1 for the appropriate endpoint zero

memory locations.

The Mode bits (bits [3:0]) control how the endpoint responds to USB bus traffic. Th e mode bit encoding is shown in T a ble 18-1.

[5]

Additional information on the mode bits can be found in Table 18-2 and T a ble 18-3.

17.4

USB Non-control Endpoint Mode Registers

The format of the non-control endpoint mode registers is shown in Figure 17-3.

USB Non-control Device Endpoint Mode

Addresses 0x14, 0x16, 0x44

Bit #

STALL

R/W

Reserved

R/W

Reserved

R/W

Bit Name

Read/Write

Reset

ACK

R/W

Mode Bit 3 Mode Bit 2 Mode Bit 1 Mode Bit 0

R/W

Figure 17-3. USB Non-control Device Endpoint Mode Registers

Bits[3..0] : Mode.

These sets the mode which control how the control endpoint responds to traffic. The mode bit encoding is shown in

Table 18-1.

Bit 4 : ACK.

This bit is set whenever the SIE engages in a transaction to the register’s endpoint that completes with an ACK packet.

Bits[6..5]: Reserved.

Must be written zero during register writes.

Bit 7: STALL.

If this STALL is set, the SIE stalls an OUT packet if the mode bits are set to ACK-IN, and the SIE stalls an IN packet if the

mode bits are set to ACK-OUT. For all other modes, the STALL bit must be a LOW.

17.5

USB Endpoint Counter Registers

There are five Endpoint Counter registers, with identical formats for both control and non-control endpoints. These registers

contain byte count information for USB transactions, as well as bits for data packet status. The format of these registers is shown

in Figure 17-4.

USB Endpoint Counter

Addresses 0x11, 0x13, 0x15, 0x41, 0x43

Bit #

Bit Name

Data 0/1

Toggle

Data Valid Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

Bit 5

R/W

Bit 4

R/W

Bit 3

R/W

Bit 2

R/W

Bit 1

R/W

Bit 0

R/W

Read/Write

Reset

R/W

Figure 17-4. USB Endpoint Counter Registers

Bits[5..0]: Byte Count.

These counter bits indicate the number of data bytes in a transaction. For IN transactions, firmware loads the count with

the number of bytes to be transmitted to the host from the endpoint FIFO. Valid values are 0 to 32, inclusive. For OUT or

SETUP transactions, the count is updated by hardware to the number of data bytes received, plus two for the CRC bytes.

Valid values are 2 to 34, inclusive.

Note:

5. The SIE offers an “Ack out – Status in” mode and not an “Ack out – Nak in” mode. Therefore, if following the status stage of a Control Write transfer a USB host

were to immediately start the next transfer, the new Setup packet could override the data payload of the data stage of the previous Control Write.

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Bit 6: Data Valid.

This bit is set on receiving a proper CRC when the endpoint FIFO buffer is loaded with data during transactions. This bit is

used OUT and SETUP tokens only. If the CRC is not correct, the endpoint interrupt occurs, but Data Valid is cleared to a

zero.

Bit 7: Data 0/1 Toggle.

This bit selects the DATA packet’s toggle state: 0 for DATA0, 1 for DATA1. For IN transactions, firmware must set this bit to

the desired state. For OUT or SETUP transactions, the hardware sets this bit to the state of the received Data Toggle bit.

Whenever the count updates from a SETUP or OUT transaction on endpoint 0, the counter register locks and cannot be written

by the CPU. Reading the register unlocks it. This prevents firmware from overwriting a status update on incoming SETUP or OUT

transactions before firmware has a chance to read the data. Only endpoint 0 counter register is locked when updated. The locking

mechanism does not apply to the count registers of other endpoints.

17.6

Endpoint Mode/Count Registers Update and Locking Mechanism

The contents of the endpoint mode and counter registers are updated, based on the packet flow diagram in Figure 17-5. Two

time points, SETUP and UPDATE, are shown in the same figure. The following activities occur at each time point:

SETUP:

The SETUP bit of the endpoint 0 mode register is forced HIGH at this time. This bit is forced HIGH by the SIE until the end of the

data phase of a control write transfer. The SETUP bit can not be cleared by firmware during this time.

The affected mode and counter registers of endpoint 0 are locked from any CPU writes once they are updated. These registers

can be unlocked by a CPU read, only if the read operation occurs after the UPDATE. The firmware needs to perform a register

read as a part of the endpoint ISR processing to unlock the effected registers. The locking mechanism on mode and counter

registers ensures that the firmware recognizes the changes that the SIE might have made since the previous IO read of that

UPDATE:

1. Endpoint Mode Register – All the bits are updated (except the SETUP bit of the endpoint 0 mode register).

2. Counter Registers – All bits are updated.

3. Interrupt – If an interrupt is to be generated as a result of the transaction, the interrupt flag for the corresponding endpoint is

set at this time. For details on what conditions are required to generate an endpoint interrupt, refer to Table 18-2.

4. The contents of the updated endpoint 0 mode and counter registers are locked, except the SETUP bit of the endpoint 0 mode

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1. IN Token

Host To Device

Device To Host

Host To Device

Data

1/0

Hand

Shake

Packet

Token Packet

Data Packet

UPDATE

Host To Device

Device To Host

NAK/STALL

Token Packet

Data Packet

UPDATE

2. OUT or SETUP Token without CRC error

Device To Host

Host To Device

ACK,

Data

NAK,

STAL

Set

1/0

Hand

Shake

Packet

Token Packet

Data Packet

UPDATE

SETUP

3. OUT or SETUP Token with CRC error

Host To Device

1/0

Data

Set

Token Packet

Data Packet

UPDATE only if FIFO is

written

Figure 17-5. Token/Data Packet Flow Diagram

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18.0

USB Mode Tables

Table 18-1. USB Register Mode Encoding

Mode

Moder

Disable

Bits SETUP

0000 ignore

0001 accept

0010 accept

0011 accept

0100 accept

0101 ignore

OUT

Comments

ignore ignore Ignore all USB traffic to this endpoint

Nak In/Out

NAK

stall

NAK Forced from Setup on Control endpoint, from modes other than 0000

check For Control endpoints

Status Out Only

Stall In/Out

stall For Control endpoints

Ignore In/Out

Isochronous Out

Status In Only

Isochronous In

Nak Out

ignore ignore For Control endpoints

ignore always For Isochronous endpoints

0110 accept TX 0 Byte stall For Control Endpoints

0111 ignore TX Count ignore For Isochronous endpoints

1000 ignore

ignore

NAK Is set by SIE on an ACK from mode 1001 (Ack Out)

[6]

Ack Out(STALL =0) 1001 ignore

ignore

ACK On issuance of an ACK this mode is changed by SIE to 1000 (NAK

stall Out)

[6]

AckOut(STALL =1) 1001 ignore

Nak Out - Status In

Ack Out - Status In

1010 accept TX 0 Byte NAK Is set by SIE on an ACK from mode 1011 (Ack Out – Status In)

1011 accept TX 0 Byte ACK On issuance of an ACK this mode is changed by SIE to 1010 (NAK

Out – Status In)

Nak In

1100 ignore

NAK

ignore Is set by SIE on an ACK from mode 1101 (Ack In)

[6]

Ack IN(STALL =0) 1101 ignore TX Count ignore On issuance of an ACK this mode is changed by SIE to 1100 (NAK In)

[6]

Ack IN(STALL =1) 1101 ignore

stall

ignore

Nak In - Status Out

Ack In - Status Out

1110 accept

NAK

check Is set by SIE on an ACK from mode 1111 (Ack In – Status Out)

1111 accept TX Count check On issuance of an ACK this mode is changed by SIE to 1110 (NAK In

– Status Out)

Mode

This lists the mnemonic given to the different modes that can be set in the Endpoint Mode Register by writing to the lower nibble

(bits 0..3). The bit settings for different modes are covered in the column marked “Mode Bits”. The Status IN and Status OUT

represent the Status stage in the IN or OUT transfer involving the control endpoint.

Mode Bits

These column lists the encoding for different modes by setting Bits[3..0] of the Endpoint Mode register. This modes represents

how the SIE responds to different tokens sent by the host to an endpoint. For instance, if the mode bits are set to “0001” (NAK

IN/OUT), the SIE will respond with an

• ACK on receiving a SETUP token from the host.

• NAK on receiving an OUT token from the host.

• NAK on receiving an IN token from the host.

Refer to Section 13.0 for more information on the SIE functioning.

SETUP, IN, and OUT

These columns shows the SIE’s response to the host on receiving a SETUP, IN and OUT token depending on the mode set in

the Endpoint Mode Register.

A “Check” on the OUT token column, implies that on receiving an OUT token the SIE checks to see whether the OUT packet is

of zero length and has a Data Toggle (DTOG) set to ‘1.’ If the DTOG bit is set and the received OUT Packet has zero length, the

OUT is ACKed to complete the transaction. If either of this condition is not met the SIE will respond with a STALLL or just ignore

the transaction.

A “TX Count” entry in the IN column implies that the SIE transmit the number of bytes specified in the Byte Count (bits 3..0 of the

Endpoint Count Register) to the host in response to the IN token received.

A “TX0 Byte” entry in the IN column implies that the SIE transmit a zero length byte packet in response to the IN token received

from the host.

An “Ignore” in any of the columns means that the device will not send any handshake tokens (no ACK) to the host.

An “Accept” in any of the columns means that the device will respond with an ACK to a valid SETUP transaction to the host.

Note:

6. STALL bit is bit 7 of the USB Non-control Device Endpoint Mode registers. For more information, refer to Section 17.4.

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Comments

Some Mode Bits are automatically changed by the SIE in response to certain USB transactions. For example, if the Mode Bits

[3:0] are set to '1111' which is ACK IN-Status OUT mode as shown in Table 18-1, the SIE will change the endpoint Mode Bits [3:0]

to NAK IN-Status OUT mode (1110) after ACK’ing a valid status stage OUT token. The firmware needs to update the mode for

the SIE to respond appropriately. See Table 18-1 for more details on what modes will be changed by the SIE. A disabled endpoint

will remain disabled until changed by firmware, and all endpoints reset to the disabled mode (0000). Firmware normally enables

the endpoint mode after a SetConfiguration request.

Any SETUP packet to an enabled endpoint with mode set to accept SETUPs will be changed by the SIE to 0001 (NAKing INs

and OUTs). Any mode set to accept a SETUP will send an ACK handshake to a valid SETUP token.

The control endpoint has three status bits for identifying the token type received (SETUP, IN, or OUT), but the endpoint must be

placed in the correct mode to function as such. Non-control endpoints should not be placed into modes that accept SETUPs.

Note that most modes that control transactions involving an ending ACK, are changed by the SIE to a corresponding mode which

NAKs subsequent packets following the ACK. Exceptions are modes 1010 and 1110

Table 18-2. Decode table for Table 18-3: “Details of Modes for Differing Traffic Condition

Properties of Incoming

Packets

Changes to the Internal Register made by the SIE on receiving an incoming packet

from the host

Interrupt

Token

count

buffer

dval

DTOG

DVAL

COUNT

Setup

Out

ACK

Response Int

Byte Count (bits 0..5, Figure 17-4)

Data Valid (bit 6, Figure 17-4)

Endpoint Mode

encoding

SIE’s Response

to the Host

Received Token

(SETUP/IN/OUT)

Data0/1 (bit7 Figure 17-4)

PID Status Bits

(Bit[7..5], Figure 17-2)

Endpoint Mode bits

Changed by the SIE

The validity of the received data

The quality status of the DMA buffer

The number of received bytes

Acknowledge phase completed

Legend:

TX : transmit

RX : receive

UC : unchanged

TX0 :Transmit 0 length packet

available for Control endpoint only

x: don’t care

The response of the SIE can be summarized as follows:

1. The SIE will only respond to valid transactions, and will ignore non-valid ones.

2. The SIE will generate an interrupt when a valid transaction is completed or when the FIFO is corrupted. FIFO corruption occurs

during an OUT or SETUP transaction to a valid internal address, that ends with a non-valid CRC.

3. An incoming Data packet is valid if the count is < Endpoint Size + 2 (includes CRC) and passes all error checking;

4. An IN will be ignored by an OUT configured endpoint and visa versa.

5. The IN and OUT PID status is updated at the end of a transaction.

6. The SETUP PID status is updated at the beginning of the Data packet phase.

7. The entire Endpoint 0 mode register and the Count register are locked to CPU writes at the end of any transaction to that

endpoint in which an ACK is transferred. These registers are only unlocked by a CPU read of the register, which should be

done by the firmware only after the transaction is complete. This represents about a 1-µs window in which the CPU is locked

from register writes to these USB registers. Normally the firmware should perform a register read at the beginning of the

Endpoint ISRs to unlock and get the mode register information. The interlock on the Mode and Count registers ensures that

the firmware recognizes the changes that the SIE might have made during the previous transaction. Note that the setup bit of

the mode register is NOT locked. This means that before writing to the mode register, firmware must first read the register to

make sure that the setup bit is not set (which indicates a setup was received, while processing the current USB request). This

read will of course unlock the register. So care must be taken not to overwrite the register elsewhere.

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Table 18-3. Details of Modes for Differing Traffic Conditions (see Table 18-2 for the decode legend)

SETUP (if accepting SETUPs)

Properties of Incoming Packet

Changes made by SIE to Internal Registers and Mode Bits

Mode Bits

token

count buffer

dval

valid

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

ACK

Intr

yes

See Table 18-1 Setup

<= 10 data

updates

UC UC

> 10

junk

updates updates updates

updates updates

NoChange ignore

invalid

Properties of Incoming Packet

Changes made by SIE to Internal Registers and Mode Bits

Mode Bits

token

count buffer

dval

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

Intr

DISABLED

UC UC

NoChange ignore

Nak In/Out

Out

NoChange NAK

yes

Ignore In/Out

Out

UC UC

NoChange ignore

Stall In/Out

Out

NoChange Stall

yes

CONTROL WRITE

Properties of Incoming Packet

Mode Bits token count buffer

Normal Out/premature status In

Changes made by SIE to Internal Registers and Mode Bits

dval

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

Intr

Out

<= 10 data

valid

updates

updates UC

ACK

yes

> 10

junk

updates updates updates UC

NoChange ignore

NoChange TX 0

invalid

updates

updates UC

NAK Out/premature status In

Out

<= 10 UC

valid

NoChange NAK

NoChange ignore

NoChange TX 0

yes

> 10

UC UC

invalid

yes

Status In/extra Out

Out

<= 10 UC

valid

Stall

yes

> 10

UC UC

NoChange ignore

NoChange TX 0

invalid

yes

CONTROL READ

Properties of Incoming Packet

Mode Bits token count buffer

Normal In/premature status Out

Changes made by SIE to Internal Registers and Mode Bits

dval

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

Intr

Out

valid

updates UC

NoChange ACK

yes

Stall

!=2

> 10

updates

UC UC

NoChange ignore

invalid

ACK (back)

yes

Nak In/premature status Out

Out

valid

updates UC

NoChange ACK

yes

Stall

!=2

> 10

updates

UC UC

NoChange ignore

NoChange NAK

invalid

yes

Status Out/extra In

Out

valid

updates UC

NoChange ACK

yes

Stall

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CY7C65113C

Table 18-3. Details of Modes for Differing Traffic Conditions (see Table 18-2 for the decode legend) (continued)

Out

!=2

> 10

valid

updates

updates UC

Stall

yes

UC UC

NoChange ignore

invalid

Stall

yes

OUT ENDPOINT

Properties of Incoming Packet

Changes made by SIE to Internal Registers and Mode Bits

Mode Bits

token

count buffer

dval

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

Intr

Normal Out/erroneous In

Out

<= 10 data

valid

updates

updates UC

ACK

yes

> 10

junk

updates updates updates UC

NoChange ignore

invalid

updates

updates UC

UC UC

[6]

(STALL = 0)

NoChange Stall

(STALL = 1)

UC UC

[6]

NAK Out/erroneous In

Out

<= 10 UC

valid

NoChange NAK

yes

> 10

UC UC

NoChange ignore

invalid

Isochronous endpoint (Out)

Out

updates updates

updates updates updates UC

UC UC UC UC

NoChange RX

yes

UC UC

NoChange ignore

IN ENDPOINT

Properties of Incoming Packet

Mode Bits token count buffer

Normal In/erroneous Out

Changes made by SIE to Internal Registers and Mode Bits

dval

DTOG

DVAL

COUNT Setup

Out ACK

Mode Bits Response

Intr

Out

UC UC

NoChange ignore

[6]

(STALL = 0)

NoChange stall

[6]

(STALL = 1)

ACK (back)

yes

NAK In/erroneous Out

Out

UC UC

NoChange ignore

NoChange NAK

yes

Isochronous endpoint (In)

Out

UC UC

NoChange ignore

NoChange TX

yes

Document #: 38-08002 Rev. *D

Page 42 of 49

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CY7C65113C

19.0

Address

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Read/Write/B

oth/–[7]

Default/

Reset

0x00

0x01

0x02

0x03

0x04

Port 0 Data

P0.7

P1.7

P2.7

P3.7

P0.6

P1.6

P2.6

P3.6

P0.5

P1.5

P2.5

P3.5

P0.4

P1.4

P2.4

P3.4

P0.3

P1.3

P2.3

P3.3

P0.2

P1.2

P2.2

P3.2

P0.1

P1.1

P2.1

P3.1

P0.0

P1.0

P2.0

P3.0

BBBBBBBB

11111111

Port 1 Data

Port 2 Data

Port 3 Data

Port 0 Interrupt Enable

P0.7 Intr

Enable

P0.6 Intr

Enable

P0.5 Intr

Enable

P0.4 Intr

Enable

P0.3 Intr

Enable

P0.2 Intr

Enable

P0.1 Intr

Enable

P0.0 Intr

Enable

WWWWWWWW 00000000

0x05

0x08

Port 1 Interrupt Enable

GPIO Configuration

P1.7 Intr

Enable

P1.6 Intr

Enable

P1.5 Intr

Enable

P1.4 Intr

Enable

Reserved

P1.2 Intr

Enable

P1.1 Intr

Enable

P1.0 Intr

Enable

WWWWWWWW 00000000

Reserved

Port 1

Port 0

BBBBBBBB

00000000

Config Bit 1 Config Bit 0 Config Bit 1 Config Bit 0

0x09

0x10

HAPI/I C Configuration

I C Position

Reserved

I C Port

Width

Reserved

BBBBBBBB

00000000

USB Device Address A

Device

Address A

Enable

Device

Address A

Bit 6

Device

Address A

Bit 5

Device

Address A

Bit 4

Device

Address A

Bit 3

Device

Address A

Bit 2

Device

Address A

Bit 1

Device

Address A

Bit 0

0x11

0x12

EP A0 Counter

Data 0/1

Toggle

Data Valid

Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

BBBBBBBB

00000000

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

EP A0 Mode Register

Endpoint0

SETUP

Received

Endpoint0

Received

Endpoint0

OUT

ACK

Mode Bit 3

Mode Bit 2

Mode Bit 1

Mode Bit 0

Received

0x13

EP A1 Counter

Data 0/1

Toggle

Data Valid

Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

BBBBBBBB

00000000

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

0x14

0x15

EP A1 Mode Register

STALL

ACK

Mode Bit 3

Mode Bit 2

Mode Bit 1

Mode Bit 0

BBBBBBBB

00000000

EP A2 Counter

Data 0/1

Toggle

Data Valid

Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

0x16

EP A2 Mode Register

STALL

ACK

Mode Bit 3

Mode Bit 2

Mode Bit 1

Mode Bit 0

BBBBBBBB

00000000

0x1F

0x20

USB Status and Control

Global Interrupt Enable

Endpoint

Size

Endpoint

Mode

D+

D–

Bus Activity

Control

Bit 2

Control

Bit 1

Control

Bit 0

BBRRBBBB

-BBBBBBB

-0xx0000

-0000000

Upstream

Reserved

I C

GPIO

Interrupt

Enable

Reserved

USB Hub

Interrupt

Enable

1.024-ms

Interrupt

Enable

128-µs

Interrupt

Enable

USB Bus

RESET

Interrupt

Enable

Interrupt

Enable

0x21

Endpoint Interrupt

Enable

Reserved

EPB1

Interrupt

Enable

EPB0

Interrupt

Enable

EPA2

Interrupt

Enable

EPA1

Interrupt

Enable

EPA0

Interrupt

Enable

---BBBBB

---00000

0x24

0x25

Timer (LSB)

Timer (MSB)

Timer Bit 7

Reserved

Timer Bit 6

Reserved

Timer Bit 5

Reserved

Timer Bit 4

Reserved

Timer Bit 3

Timer Bit 2

Timer Bit 1

Timer Bit 0

Timer Bit 8

RRRRRRRR

----rrrr

00000000

----0000

Timer Bit 11 Timer Bit 10 Time Bit 9

0x28

I C Control and Status

MSTR

Mode

Continue/

Busy

Xmit

Mode

ACK

Addr

ARB Lost/

Restart

Received

Stop

I C

BBBBBBBB

00000000

Enable

0x29

0x40

I C Data

I C Data 7

I C Data 6

I C Data 5

I C Data 4

I C Data 3

I C Data 2

I C Data 1

I C Data 0

BBBBBBBB

XXXXXXXX

00000000

USB Device Address B

Device

Address B

Enable

Device

Address B

Bit 6

Device

Address B

Bit 5

Device

Address B

Bit 4

Device

Address B

Bit 3

Device

Address B

Bit 2

Device

Address B

Bit 1

Device

Address B

Bit 0

0x41

0x42

EP B0 Counter Register

EP B0 Mode Register

Data 0/1

Toggle

Data Valid

Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

BBBBBBBB

00000000

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Endpoint 0

SETUP

Received

Endpoint 0

Received

Endpoint 0

OUT

ACK

Mode Bit 3

Mode Bit 2

Mode Bit 1

Mode Bit 0

Received

0x43

0x44

EP B1 Counter Register

EP B1 Mode Register

Data 0/1

Toggle

Data Valid

Byte Count Byte Count Byte Count Byte Count Byte Count Byte Count

BBBBBBBB

00000000

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

STALL

ACK

Mode Bit 3

Mode Bit 2

Mode Bit 1

Mode Bit 0

Note:

7. B: Read and Write; W: Write; R: Read.

Document #: 38-08002 Rev. *D

Page 43 of 49

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CY7C65113C

19.0

Address

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Read/Write/B

oth/–[7]

Default/

Reset

0x48

Hub Port Connect Status

Reserved

Port 4

Connect

Status

Port 3

Connect

Status

Port 2

Connect

Status

Port 1

Connect

Status

BBBBBBBB

00000000

0x49

0x4A

0x4B

0x4D

Hub Port Enable

Hub Port Speed

Reserved

Port 4

Reserved

Port 4

Reserved

Port 3

Reserved

Port 3

Port 4

Port 3

Port 2

Port 1

BBBBBBBB

00000000

Enable

Port 4

Speed

Port 3

Speed

Port 2

Speed

Port 1

Speed

Hub Port Control (Ports

4:1)

Port 2

Port 1

Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0 Control Bit 1 Control Bit 0

Hub Port Suspend

Device

Remote

Wakeup

Reserved

Port 4

Selective

Suspend

Port 3

Selective

Suspend

Port 2

Selective

Suspend

Port 1

Selective

Suspend

0x4E

0x4F

Hub Port Resume Status

Hub Port SE0 Status

Reserved

Resume 4

Port 4

Resume 3

Port 3

Resume 2

Port 2

Resume 1

Port 1

-RRRRRRR

RRRRRRRR

00000000

SE0 Status SE0 Status SE0 Status SE0 Status

0x50

0x51

Hub Ports Data

Reserved

Port 4

Port 3

Port 2

Port 1

RRRRRRRR

BBBBBBBB

00000000

Diff. Data

Hub Port Force Low

(Ports 4:1)

Force Low

D+[4]

Force Low

D–[4]

Force Low

D+[3]

Force Low

D–[3]

Force Low

D+[2]

Force Low

D–[2]

Force Low

D+[1]

Force Low

D–[1]

0xFF

Process Status & Control

IRQ

Pending

Watchdog

Reset

USB Bus

Reset

Interrupt

Power-on

Reset

Suspend

Interrupt

Enable

Sense

Reserved

Run

RBBBBRBB

00010001

Document #: 38-08002 Rev. *D

Page 44 of 49

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CY7C65113C

20.0

Sample Schematic

USB-A

Vbus

D–

D+

GND

3.3V Regulator

Vref

OUT

2.2 µF

Vref

1.5K

2.2 µF

)

UUP

USB-B

0.01 µF

Vbus

D–

22x2(R

)

ext

D+

GND

USB-A

Vbus

D–

D+

GND

22x8(R

)

ext

SHELL

D0–

D0+

D1-

D1+

4.7 nF

250 VAC

Optional

D2-

XTALO

XTALI

D2+

10M

D3-

6.000 MHz

D3+

GND

Vpp

D4-

USB-A

Vbus

D–

D4+

D+

GND

15K(x8)

)

UDN

USB-A

Vbus

D–

POWER

MANAGEMENT

D+

GND

21.0

Absolute Maximum Ratings

Storage Temperature .......................................................................................................................................... –65°C to +150°C

Ambient Temperature with Power Applied................................................................................................................. 0°C to +70°C

Supply voltage on V relative to V .................................................................................................................... –0.5V to +7.0V

DC Input Voltage.......................................................................................................................................... –0.5V to +V + 0.5V

DC Voltage applied to Outputs in High Z State ............................................................................................ –0.5V to +V + 0.5V

Power Dissipation ..............................................................................................................................................................500 mW

Static Discharge Voltage ...................................................................................................................................................> 2000V

Latch-up Current ............................................................................................................................................................ > 200 mA

Max Output Sink Current into Port 0, 1 ............................................................................................................................... 60 mA

Max Output Sink Current into DAC[7:2] Pins....................................................................................................................... 10 mA

Max Output Source Current from Port 1, 2, 3, 4, 5, 6, 7 ..................................................................................................... 30 mA

Document #: 38-08002 Rev. *D

Page 45 of 49

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CY7C65113C

22.0

Electrical Characteristics

= 6 MHz; Operating Temperature = 0 to 70°C, V = 4.0V to 5.25V

OSC

Parameter

Description

Conditions

Min.

Max.

Unit

General

Reference Voltage

Programming Voltage (disabled)

Operating Current

3.3V ±5%

3.15

–0.4

3.45

0.4

REF

I_CC

No GPIO source current

µA

I_SB1

Supply Current—Suspend Mode

Operating Current

[8]

No USB Traffic

ref

REF

Input Leakage Current

Any pin

USB Interface

| (D+)–(D–) |

Differential Input Sensitivity

0.2

0.8

Differential Input Common Mode Range

Single Ended Receiver Threshold

Transceiver Capacitance

2.5

2.0

µA

Ω

Hi-Z State Data Line Leakage

External USB Series Resistor

0V < V < 3.3V

–10

In series with each USB pin

ext

External Upstream USB Pull-up Resistor 1.5 kΩ ±5%, D+ to V

1.425 1.575

14.25 15.75

kΩ

UUP

UDN

REG

External Downstream Pull-down Resistors 15 kΩ ±5%, downstream USB pins

Power-on Reset

[9]

Ramp Rate

Linear ramp 0V to V

100

vccs

USB Upstream/Downstream Port

Static Output High

15 kΩ ±5% to Gnd

2.8

3.6

0.3

Ω

UOH

Static Output Low

1.5 kΩ ±5% to V

UOL

REF

USB Driver Output Impedance

Including R Resistor

ext

General Purpose I/O (GPIO)

Pull-up Resistance (typical 14 kΩ)

Input Threshold Voltage

8.0

20%

24.0

40%

kΩ

ITH

All ports, low-to-high edge

All ports, high-to-low edge

Input Hysteresis Voltage

Port 0,1 Output Low Voltage

= 3 mA

= 8 mA

0.4

2.0

Output High Voltage

= 1.9 mA (all ports 0,1)

2.4

Notes:

8. Add 18 mA per driven USB cable (upstream or downstream. This is based on transitions every 2 full-speed bit times on average.

9. Power-on Reset occurs whenever the voltage on V is below approximately 2.5V.

Document #: 38-08002 Rev. *D

Page 46 of 49

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CY7C65113C

23.0

Switching Characteristics (f

= 6.0 MHz)

OSC

Parameter

Description

Clock Source

Min.

Max.

Unit

Clock Rate

6 ±0.25%

166.25

MHz

OSC

cyc

Clock Period

167.08

Clock HIGH time

Clock LOW time

0.45 t

CYC

[10]

USB Full-speed Signaling

Transition Rise Time

Transition Fall Time

rfs

ffs

Rise/Fall Time Matching; (t /t )

111

rfmfs

dratefs

r f

Full Speed Date Rate

12 ±0.25%

Mb/s

Timer Signals

Watchdog Timer Period

8.192

14.336

watch

Note:

10. Per Table 7-6 of revision 1.1 of USB specification.

CYC

CLOCK

D+

90%

10%

D−

Document #: 38-08002 Rev. *D

Page 47 of 49

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CY7C65113C

24.0

Ordering Information

Ordering Code

PROM Size

Package Type

Operating Range

CY7C65113C-SXC

CY7C65113C-SXCT

8 KB

28-pin SOIC

28-pin SOIC-Tape Reel

Commercial

25.0

Package Diagram

28-Lead (300-Mil) Molded SOIC

NOTE :

PIN 1 ID

1. JEDEC STD REF MO-119

2. BODY LENGTH DIMENSION DOES NOT INCLUDE MOLD PROTRUSION/END FLASH,BUT

DOES INCLUDE MOLD MISMATCH AND ARE MEASURED AT THE MOLD PARTING LINE.

MOLD PROTRUSION/END FLASH SHALL NOT EXCEED 0.010 in (0.254 mm) PER SIDE

MIN.

3. DIMENSIONS IN INCHES

MAX.

0.291[7.39]

0.300[7.62]

4. PACKAGE WEIGHT 0.85gms

0.394[10.01]

0.419[10.64]

PART #

0.026[0.66]

0.032[0.81]

S28.3 STANDARD PKG.

SZ28.3 LEAD FREE PKG.

SEATING PLANE

0.697[17.70]

0.713[18.11]

0.092[2.33]

0.105[2.67]

0.004[0.10]

0.0091[0.23]

0.0125[3.17]

0.015[0.38]

0.050[1.27]

0.013[0.33]

0.019[0.48]

0.004[0.10]

0.050[1.27]

TYP.

0.0118[0.30]

51-85026-*D

Purchase of I C components from Cypress, or one of its sublicensed Associated Companies, conveys a license under the Philips

I C Patent Rights to use these components in an I C system, provided that the system conforms to the I C Standard Specification

as defined by Philips. All product and company names mentioned in this document are the trademarks of their respective holders.

Document #: 38-08002 Rev. *D

Page 48 of 49

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 implDiesotwhantlothaedmfarnoumfacWturwerwa.sSsuommeasnaullarilssk.cofosmuc.hAulsleMaannduinadlsoinSgesaoricnhdeAmnndifieDsoCwypnrelosasda.gainst all charges.

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CY7C65113C

Document History Page

Document Title: CY7C65113C USB Hub with Microcontroller

Document Number: 38-08002

Orig. of

REV.

ECN NO. Issue Date Change

Description of Change

109965

120372

02/22/02

12/17/02

SZV

Change from Spec number: 38-00590 to 38-08002

MON

Added register bit definitions.

Added default bit state of each register.

Corrected the Schematic (location of the pull-up on D+).

Corrected the Logical Diagram (removed the extra GPIO Port 1).

Added register summary.

Modified Figure 17-5, more labeling.

Removed information on the availability of the part in PDIP package.

Modified T a ble 18-1 and provided more explanation regarding

locking/unlocking mechanism of the mode register.

Removed any information regarding the speed detect bit in Hub Port Speed

124522

368601

429098

03/13/03

See ECN

MON

BHA

TYJ

Fixed the figure on page 42 regarding the update of mode registers. The

arrows in the figure were misplaced and the figure was unreadable. This is

an important figure for understanding mode register functioning.

Added Lead-free Package Information.

Removed CY7C65013 Information.

Updated Package Drawing.

Part numbers changed to ‘C’ types

Cypress Perform logo added

Part numbers updated in the ordering section

Document #: 38-08002 Rev. *D

Page 49 of 49

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