Cypress CY7C68053 Mobl-usb fx2lp18 usb microcontroller Datasheet

CY7C68053
MoBL-USB™ FX2LP18 USB
Microcontroller
1. CY7C68053 Features
■
USB 2.0 – USB-IF High Speed and Full Speed Compliant
(TID# 40000188)
■
Ideal for Mobile Applications (Cell Phone, Smart Phones,
PDAs, MP3 Players)
❐ Ultra low power
❐ Suspend current: 20 µA (typical)
Integrated, Industry Standard Enhanced 8051
❐ 48 MHz, 24 MHz, or 12 MHz CPU operation
❐ Four clocks per instruction cycle
❐ Three counter/timers
❐ Expanded interrupt system
❐ Two data pointers
■
Single-Chip Integrated USB 2.0 Transceiver, Smart SIE,
and Enhanced 8051 Microprocessor
■
■
1.8V Core Operation
■
1.8V to 3.3V I/O Operation
■
Software: 8051 Code runs from:
❐ Internal RAM, which is loaded from EEPROM
■
Vectored USB Interrupts and GPIF/FIFO Interrupts
■
16 kBytes of On-Chip Code/Data RAM
■
Separate Data Buffers for Setup and Data Portions of a
CONTROL Transfer
■
Four Programmable BULK/INTERRUPT/ISOCHRONOUS
endpoints
❐ Buffering options: double, triple, and quad
■
Integrated I2C Controller, runs at 100 or 400 kHz
■
Four Integrated FIFOs
❐ Integrated glue logic and FIFOs lower system cost
❐ Automatic conversion to and from 16-bit buses
❐ Master or slave operation
❐ Uses external clock or asynchronous strobes
❐ Easy interface to ASIC and DSP ICs
■
Available in Industrial Temperature Grade
■
Available in one Pb-free Package with up to 24 GPIOs
❐ 56-pin VFBGA (24 GPIOs)
■
Additional Programmable (BULK/INTERRUPT) 64-Byte
Endpoint
■
8 or 16-Bit External Data Interface
■
Smart Media Standard ECC Generation
■
GPIF (General Programmable Interface)
❐ Allows direct connection to most parallel interface
❐ Programmable waveform descriptors and configuration
registers to define waveforms
❐ Supports multiple Ready and Control outputs
Block Diagram
High-performance microprocessor
using standard tools
with lower-power options
24 MHz
Ext. XTAL
MoBL-USB FX2LP18
x20
PLL
2
/0.5
/1.0
/2.0
8051 Core
12/24/48 MHz,
Four Clocks/Cycle
1.5K
Connected for
Full-Speed
D+
D–
USB
2.0
XCVR
CY
Smart
USB
1.1/2.0
Engine
Integrated
Full- and High-Speed
XCVR
16 KB
RAM
A dd re ss ( 16) / D ata Bu s (8)
VCC
I C
Master
GPIF
RDY (2)
CTL (3)
ECC
4 KB
FIFO
Enhanced USB Core
Simplifies 8051 Code
Cypress Semiconductor Corporation
Document # 001-06120 Rev *I
•
“Soft Configuration”
Easy Firmware Changes
198 Champion Court
Abundant IO
Additional IOs (24)
8/16
General
Programmable I/F
To Baseband Processors/
Application Processors/
ASICS/DSPs
Up to 96 MBytes/sec
Burst Rate
FIFO and Endpoint Memory
(Master or Slave Operation)
•
San Jose, CA 95134-1709
•
408-943-2600
Revised July 02, 2009
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CY7C68053
Cypress Semiconductor Corporation’s MoBL-USB™ FX2LP18
(CY7C68053) is a low voltage (1.8V) version of the EZ-USB®
FX2LP (CY7C68013A), which is a highly integrated, low power
USB 2.0 microcontroller. By integrating the USB 2.0 transceiver,
serial interface engine (SIE), enhanced 8051 microcontroller,
and a programmable peripheral interface in a single chip,
Cypress has created a very cost effective solution that provides
superior time-to-market advantages with low power to enable
bus powered applications.
3.2 8051 Microprocessor
The ingenious architecture of MoBL-USB FX2LP18 results in
data transfer rates of over 53 Mbytes per second, the maximum
allowable USB 2.0 bandwidth, while still using a low cost 8051
microcontroller in a package as small as a 56VFBGA (5 mm x
5 mm). Because it incorporates the USB 2.0 transceiver, the
MoBL-USB FX2LP18 is more economical, providing a smaller
footprint solution than USB 2.0 SIE or external transceiver
implementations. With MoBL-USB FX2LP18, the Cypress Smart
SIE handles most of the USB 1.1 and 2.0 protocol in hardware,
freeing the embedded microcontroller for application-specific
functions and decreasing development time to ensure USB
compatibility.
■
Parallel resonant
■
Fundamental mode
■
500 µW drive level
■
12 pF (5% tolerance) load capacitors
The General Programmable Interface (GPIF) and Master/Slave
Endpoint FIFO (8 or 16-bit data bus) provide an easy and
glueless interface to popular interfaces such as ATA, UTOPIA,
EPP, PCMCIA, and most DSP/processors.
The MoBL-USB FX2LP18 is also referred to as FX2LP18 in this
document.
2. Applications
There are a wide variety of applications for the MoBL-USB
FX2LP18. It is used in cell phones, smart phones, PDAs, and
MP3 players, to name a few.
The 8051 microprocessor embedded in the FX2LP18 family has
256 bytes of register RAM, an expanded interrupt system, and
three timer/counters.
3.2.1 8051 Clock Frequency
FX2LP18 has an on-chip oscillator circuit that uses an external
24 MHz (±100-ppm) crystal with the following characteristics:
An on-chip PLL multiplies the 24 MHz oscillator up to 480 MHz,
as required by the transceiver/PHY; internal counters divide it
down for use as the 8051 clock. The default 8051 clock
frequency is 12 MHz. The clock frequency of the 8051 can be
changed by the 8051 through the CPUCS register, dynamically.
Figure 1. Crystal Configuration
C1
24 MHz
12 pF
C2
12 pF
20 × PLL
12 pF capacitor values assumes a trace capacitance
of 3 pF per side on a four-layer FR4 PCA
The ‘Reference Designs’ section of the Cypress web site
provides additional tools for typical USB 2.0 applications. Each
reference design comes complete with firmware source and
object code, schematics, and documentation. For more
information, visit http://www.cypress.com.
The CLKOUT pin, which can be tristated and inverted using
internal control bits, outputs the 50% duty cycle 8051 clock, at
the selected 8051 clock frequency — 48, 24, or 12 MHz.
3. Functional Overview
3.2.2 Special Function Registers
The functionality of this chip is described in the sections below.
Certain 8051 Special Function Register (SFR) addresses are
populated to provide fast access to critical FX2LP18 functions.
These SFR additions are shown in Table 1 on page 3. Bold type
indicates non standard, enhanced 8051 registers. The two SFR
rows that end with ‘0’ and ‘8’ contain bit-addressable registers.
The four I/O ports A–D use the SFR addresses used in the
standard 8051 for ports 0–3, which are not implemented in
FX2LP18. Because of the faster and more efficient SFR
addressing, the FX2LP18 I/O ports are not addressable in
external RAM space (using the MOVX instruction).
3.1 USB Signaling Speed
FX2LP18 operates at two of the three rates defined in the USB
Specification Revision 2.0, dated April 27, 2000.
■
Full speed, with a signaling bit rate of 12 Mbps
■
High speed, with a signaling bit rate of 480 Mbps
FX2LP18 does not support the low speed signaling mode of
1.5 Mbps.
Document # 001-06120 Rev *I
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CY7C68053
Table 1. Special Function Registers
x
8x
9x
Ax
Bx
Cx
Dx
Ex
Fx
0
IOA
IOB
IOC
IOD
SCON1
PSW
ACC
B
INT2CLR
IOE
SBUF1
EICON
EIE
EIP
1
SP
EXIF
2
DPL0
MPAGE
3
DPH0
OEB
4
DPL1
OEC
5
DPH1
OED
6
DPS
OEE
7
PCON
8
TCON
9
TMOD
SBUF0
A
TL0
AUTOPTRH1
B
TL1
C
TH0
D
TH1
AUTOPTRH2
GPIFSGLDATH
E
CKCON
AUTOPTRL2
GPIFSGLDATLX
F
SCON0
OEA
IE
IP
T2CON
EP2468STAT
EP01STAT
RCAP2L
AUTOPTRL1
EP24FIFOFLGS
GPIFTRIG
RCAP2H
Reserved
EP68FIFOFLGS
Reserved
AUTOPTRSET-UP
3.3 I2C™ Bus
FX2LP18 supports the I2C bus as a master only at
100 or 400 KHz. SCL and SDA pins have open-drain outputs
and hysteresis inputs. These signals must be pulled up to either
VCC or VCC_IO, even if no I2C device is connected. (Connecting
to VCC_IO may be more convenient.)
3.4 Buses
This 56-pin package has an 8- or 16-bit ‘FIFO’ bidirectional data
bus, multiplexed on I/O ports B and D.
3.5 USB Boot Methods
During the power up sequence, internal logic checks the I2C port
for the connection of an EEPROM whose first byte is 0xC2. If
found, it boot-loads the EEPROM contents into internal RAM
(0xC2 load). If no EEPROM is present, an external processor
must emulate an I2C slave. The FX2LP18 does not enumerate
using internally stored descriptors (for example, Cypress’s
VID/PID/DID is not used for enumeration).[1]
3.6 ReNumeration™
Because the FX2LP18’s configuration is soft, one chip can take
on the identities of multiple distinct USB devices.
TL2
TH2
GPIFSGLDATLNOX
simulate a USB disconnect, the firmware sets DISCON to 1. To
reconnect, the firmware clears DISCON to 0.
Before reconnecting, the firmware sets or clears the RENUM bit
to indicate whether the firmware or the Default USB Device
handles device requests over endpoint zero: if RENUM = 0, the
Default USB Device handles device requests; if RENUM = 1, the
firmware does.
3.7 Bus-Powered Applications
The FX2LP18 fully supports bus-powered designs by
enumerating with less than 100 mA as required by the USB 2.0
specification.
3.8 Interrupt System
The FX2LP18 interrupts are described in this section.
3.8.1 INT2 Interrupt Request and Enable Registers
FX2LP18 implements an autovector feature for INT2. There are
27 INT2 (USB) vectors. See the MoBL-USB™ Technical
Reference Manual (TRM) for more details.
3.8.2 USB Interrupt Autovectors
When first plugged into USB, the FX2LP18 enumerates
automatically and downloads firmware and USB descriptor
tables over the USB cable. Next, the FX2LP18 enumerates
again, this time as a device defined by the downloaded
information. This patented two-step process, called
ReNumeration™, happens instantly when the device is plugged
in, with no hint that the initial download step has occurred.
The main USB interrupt is shared by 27 interrupt sources. To
save the code and processing time that is normally required to
identify the individual USB interrupt source, the FX2LP18
provides a second level of interrupt vectoring, called
‘Autovectoring.’ When a USB interrupt is asserted, the FX2LP18
pushes the program counter onto its stack then jumps to address
0x0043, where it expects to find a ‘jump’ instruction to the USB
interrupt service routine.
Two control bits in the USBCS (USB Control and Status) register
control the ReNumeration process: DISCON and RENUM. To
The FX2LP18 jump instruction is encoded as shown in Table 2
on page 4.
Note
1. The I2C bus SCL and SDA pins must be pulled up, even if an EEPROM is not connected. Otherwise this detection method does not work properly.
Document # 001-06120 Rev *I
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If Autovectoring is enabled (AV2EN = 1 in the INTSET-UP
register), the FX2LP18 substitutes its INT2VEC byte. Therefore,
if the high byte (‘page’) of a jump-table address is preloaded at
location 0x0044, the automatically inserted INT2VEC byte at
0x0045 directs the jump to the correct address out of the 27
addresses within the page.
Table 2. INT2 USB Interrupts
Priority
INT2VEC Value
1
00
SUDAV
Source
Setup data available
Notes
2
04
SOF
Start of frame (or microframe)
3
08
SUTOK
Setup token received
4
0C
SUSPEND
USB suspend request
5
10
USB RESET
Bus reset
6
14
HISPEED
Entered high speed operation
7
18
EP0ACK
FX2LP18 ACK’d the control handshake
8
1C
9
20
EP0-IN
EP0-IN ready to be loaded with data
10
24
EP0-OUT
EP0-OUT has USB data
11
28
EP1-IN
EP1-IN ready to be loaded with data
12
2C
EP1-OUT
EP1-OUT has USB data
13
30
EP2
IN: buffer available. OUT: buffer has data
14
34
EP4
IN: buffer available. OUT: buffer has data
15
38
EP6
IN: buffer available. OUT: buffer has data
16
3C
EP8
IN: buffer available. OUT: buffer has data
17
40
IBN
IN-Bulk-NAK (any IN endpoint)
18
44
19
48
EP0PING
EP0 OUT was pinged and it NAK’d
20
4C
EP1PING
EP1 OUT was pinged and it NAK’d
21
50
EP2PING
EP2 OUT was pinged and it NAK’d
22
54
EP4PING
EP4 OUT was pinged and it NAK’d
23
58
EP6PING
EP6 OUT was pinged and it NAK’d
24
5C
EP8PING
EP8 OUT was pinged and it NAK’d
25
60
ERRLIMIT
Bus errors exceeded the programmed limit
Reserved
Reserved
26
64
27
68
28
6C
29
70
EP2ISOERR
ISO EP2 OUT PID sequence error
30
74
EP4ISOERR
ISO EP4 OUT PID sequence error
31
78
EP6ISOERR
ISO EP6 OUT PID sequence error
32
7C
EP8ISOERR
ISO EP8 OUT PID sequence error
Document # 001-06120 Rev *I
Reserved
Reserved
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Figure 2. Reset Timing Plots
RESET#
RESET#
VIL
VIL
1.8V
1.62V
1.8V
VCC
VCC
0V
0V
TRESET
TRESET
Power on Reset
3.9 Reset and Wakeup
The reset and wakeup pins are described in detail in this section.
3.9.1 Reset Pin
The input pin, RESET#, resets the FX2LP18 when asserted.
This pin has hysteresis and is active LOW. When a crystal is
used with the CY7C68053, the reset period must allow for the
stabilization of the crystal and the PLL. This reset period must be
approximately 5 ms after VCC has reached 3.0V. If the crystal
input pin is driven by a clock signal the internal PLL stabilizes in
200 μs after VCC has reached 3.0V[2]. Figure 2 shows a power
on reset condition and a reset applied during operation. A power
on reset is defined as the time reset is asserted while power is
being applied to the circuit. A powered reset is defined as a reset
in which the FX2LP18 has previously been powered on and
operating and the RESET# pin is asserted.
Cypress provides an application note which describes and
recommends power on reset implementation, which can be
found on the Cypress web site. For more information on reset
implementation for the MoBL-USB family of products, visit the
Cypress web site at http://www.cypress.com.
Table 3. Reset Timing Values
Condition
Power on reset with crystal
Power on reset with external
clock
Powered reset
Powered Reset
The FX2LP18 exits the power down (USB suspend) state using
one of the following methods:
■
USB bus activity (if D+/D– lines are left floating, noise on these
lines may indicate activity to the FX2LP18 and initiate a
wakeup)
■
External logic asserts the WAKEUP pin
■
External logic asserts the PA3/WU2 pin
The second wakeup pin, WU2, can also be configured as a
general purpose I/O pin. This allows a simple external R-C
network to be used as a periodic wakeup source. Note that
WAKEUP is active LOW by default.
3.9.3 Lowering Suspend Current
Good design practices for CMOS circuits dictate that any unused
input pins must not be floating between VIL and VIH. Floating
input pins will not damage the chip, but can substantially
increase suspend current. To achieve the lowest suspend
current, confiigure unused port pins as outputs. Connect unused
input pins to ground. Some examples of pins that need attention
during suspend are:
■
Port pins. For Port A, B, D pins, take extra care in shared bus
situations.
❐ Connect completely unused pins to VCC_IO or GND.
❐ In a single-master system, the firmware must output enable
all the port pins and drive them high or low, before FX2LP18
enters the suspend state.
❐ In a multi-master system (FX2LP18 and another processor
sharing a common data bus), when FX2LP18 is suspended,
the external master must drive the pins high or low. The
external master must not let the pins float.
■
CLKOUT. If CLKOUT is not used, it must be tri-stated during
normal operation, but driven during suspend.
■
IFCLK, RDY0, RDY1. These pins must be pulled to VCC_IO or
GND or driven by another chip.
TRESET
5 ms
200 μs + clock stability time
200 μs
3.9.2 Wakeup Pins
The 8051 puts itself and the rest of the chip into a power-down
mode by setting PCON.0 = 1. This stops the oscillator and PLL.
When WAKEUP is asserted by external logic, the oscillator
restarts, after the PLL stabilizes, and then the 8051 receives a
wakeup interrupt. This applies whether or not FX2LP18 is
connected to the USB.
Note
2. If the external clock is powered at the same time as the CY7C680xx and has a stabilization wait period, it must be added to the 200 μs.
Document # 001-06120 Rev *I
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CY7C68053
■
CTL0-2. If tri-stated via GPIFIDLECTL, these pins must be
pulled to VCC_IO or GND or driven by another chip.
■
RESET#, WAKEUP#. These pins must be pulled to VCC_IO or
GND or driven by another chip during suspend.
3.11 Register Addresses
Figure 4. Register Address Memory
FFFF
4 kBytes EP2-EP8
buffers
(8 x 512)
Figure 3. FX2LP18 Internal Code Memory
FFFF
F000
EFFF
7.5 kBytes
USB regs and
4K FIFO buffers
2 kBytes RESERVED
E800
E7FF
E7C0
E7BF
E780
E77F
E740
E200
E1FF 0.5 kBytes RAM
E000 Data
.
E73F
E700
E6FF
.
.
E500
E4FF
E480
E47F
3FFF
E400
E3FF
E200
E1FF
16 kBytes RAM
Code and Data
64 Bytes EP1IN
64 Bytes EP1OUT
64 Bytes EP0 IN/OUT
64 Bytes RESERVED
8051 Addressable Registers
(512)
Reserved (128)
128 Bytes GPIF Waveforms
Reserved (512)
512 Bytes
8051 xdata RAM
E000
0000
3.12 Endpoint RAM
This section describes the FX2LP18 Endpoint RAM.
3.10 Program/Data RAM
This section describes the FX2LP18 RAM.
3.10.1 Size
The FX2LP18 has 16 kBytes of internal program/data RAM. No
USB control registers appear in this space.
3.12.1 Size
■
3 × 64 bytes (Endpoints 0, 1)
■
8 × 512 bytes (Endpoints 2, 4, 6, 8)
3.12.2 Organization
Memory maps are shown in Figure 3 and Figure 4.
■
EP0
3.10.2 Internal Code Memory
■
Bidirectional endpoint zero, 64-byte buffer
This mode implements the internal 16-kByte block of RAM
(starting at 0) as combined code and data memory. Only the
internal 16 kBytes and scratch pad 0.5 kBytes RAM spaces
have the following access:
■
EP1IN, EP1OUT
■
64-byte buffers: bulk or interrupt
■
EP2, 4, 6, 8
■
Eight 512-byte buffers: bulk, interrupt, or isochronous. EP4 and
EP8 can be double buffered, while EP2 and 6 can be double,
triple, or quad buffered. For high speed endpoint configuration
options, see Figure 5 on page 7.
■
USB download
■
USB upload
■
Setup data pointer
■
I2C interface boot load
3.12.3 Setup Data Buffer
A separate 8-byte buffer at 0xE6B8-0xE6BF holds the setup data
from a CONTROL transfer.
Document # 001-06120 Rev *I
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3.12.4 Endpoint Configurations (High Speed Mode)
Endpoints 0 and 1 are the same for every configuration. Endpoint
0 is the only CONTROL endpoint, and endpoint 1 can be either
BULK or INTERRUPT. The endpoint buffers can be configured
in any one of the 12 configurations shown in the vertical columns
of Figure 5. When operating in full speed BULK mode only the
first 64 bytes of each buffer are used. For example, in high speed
the maximum packet size is 512 bytes, but in full speed it is 64
bytes. Even though a buffer is configured to be a 512 byte buffer,
in full speed only the first 64 bytes are used. The unused
endpoint buffer space is not available for other operations. An
example endpoint configuration is:
EP2–1024 double buffered; EP6–512 quad buffered (column 8).
Figure 5. Endpoint Configuration
EP0 IN&OUT
64
64
64
64
64
64
64
64
64
64
64
64
EP1 IN
64
64
64
64
64
64
64
64
64
64
64
64
EP1 OUT
64
64
64
64
64
64
64
64
64
64
64
64
EP2
EP2
EP2
EP2
EP2
EP2
EP2
EP2
EP2
EP2
512
512
512
512
512
512
512
512
512
512
512
512
EP4
EP4
512
512
512
512
512
512
512
512
512
512
512
512
EP6
EP6
EP6
EP6
EP6
EP6
512
512
512
512
512
1024
EP8
512
512
1024
512
512
512
1
2
1024
1024
1024
512
1024
3
1024
1024
1024
1024
512
512
512
512
4
5
1024
EP6
1024
1024
512
EP6
EP6
512
512
512
512
EP6
512
1024
512
EP8
EP8
512
1024
512
EP4
512
EP2 EP2
512
512
512
512
512
7
8
6
1024
9
1024
1024
EP8
EP8
512
512
512
512
10
11
1024
1024
12
3.12.5 Default Full Speed Alternate Settings
Table 4. Default Full Speed Alternate Settings[3, 4]
Alternate Setting
0
1
2
3
ep0
64
64
64
64
ep1out
0
64 bulk
64 int
64 int
ep1in
0
64 bulk
64 int
64 int
ep2
0
64 bulk out (2×)
64 int out (2×)
64 iso out (2×)
ep4
0
64 bulk out (2×)
64 bulk out (2×)
64 bulk out (2×)
ep6
0
64 bulk in (2×)
64 int in (2×)
64 iso in (2×)
ep8
0
64 bulk in (2×)
64 bulk in (2×)
64 bulk in (2×)
Notes
3. ‘0’ means ‘not implemented.’
4. ‘2×’ means ‘double buffered.’
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CY7C68053
3.12.6 Default High Speed Alternate Settings
Table 5. Default High Speed Alternate Settings[3, 4]
Alternate Setting
0
1
2
3
ep0
64
64
64
64
ep1out
0
512 bulk[5]
64 int
64 int
ep1in
0
512 bulk[5]
64 int
64 int
ep2
0
512 bulk out (2×)
512 int out (2×)
512 iso out (2×)
ep4
0
512 bulk out (2×)
512 bulk out (2×)
512 bulk out (2×)
ep6
0
512 bulk in (2×)
512 int in (2×)
512 iso in (2×)
ep8
0
512 bulk in (2×)
512 bulk in (2×)
512 bulk in (2×)
3.13 External FIFO Interface
The architecture, control signals, and clock rates are presented
in this section.
3.13.1 Architecture
The FX2LP18 slave FIFO architecture has eight 512-byte blocks
in the endpoint RAM that directly serve as FIFO memories and
are controlled by FIFO control signals (such as IFCLK, SLCS#,
SLRD, SLWR, SLOE, PKTEND, and flags).
In operation, some of the eight RAM blocks fill or empty from the
SIE while the others are connected to the I/O transfer logic. The
transfer logic takes two forms: the GPIF for internally generated
control signals or the slave FIFO interface for externally
controlled transfers.
3.13.2 Master/Slave Control Signals
The FX2LP18 endpoint FIFOs are implemented as eight
physically distinct 256x16 RAM blocks. The 8051/SIE can switch
any of the RAM blocks between two domains, the USB (SIE)
domain and the 8051-I/O Unit domain. This switching is
instantaneous, giving zero transfer time between ‘USB FIFOs’
and ‘Slave FIFOs’. Because they are physically the same
memory, no bytes are actually transferred between buffers.
At any given time, some RAM blocks are filling and emptying with
USB data under SIE control, while other RAM blocks are
available to the 8051, the I/O control unit, or both. The RAM
blocks operate as single port in the USB domain, and dual port
in the 8051-I/O domain. The blocks can be configured as single,
double, triple, or quad buffered as previously shown.
The I/O control unit implements either an internal master (M for
master) or external master (S for Slave) interface.
In Master (M) mode, the GPIF internally controls FIFOADR[1:0]
to select a FIFO. The two ready (RDY) pins can be used as flag
inputs from an external FIFO or other logic. The GPIF can be run
from either an internally derived clock or externally supplied
clock (IFCLK), at a rate that transfers data up to 96 megabytes/s
(48 MHz IFCLK with 16-bit interface).
In Slave (S) mode, the FX2LP18 accepts either an internally
derived clock or externally supplied clock (IFCLK, maximum
frequency 48 MHz) and SLCS#, SLRD, SLWR, SLOE, PKTEND
signals from external logic. When using an external IFCLK, the
external clock must be present before switching to the external
clock with the IFCLKSRC bit. Each endpoint can individually be
selected for byte or word operation by an internal configuration
bit, and a Slave FIFO Output Enable signal (SLOE) enables data
of the selected width. External logic must insure that the output
enable signal is inactive when writing data to a slave FIFO. The
slave interface can also operate asynchronously, where the
SLRD and SLWR signals act directly as strobes, rather than a
clock qualifier as in synchronous mode. The signals SLRD,
SLWR, SLOE, and PKTEND are gated by the signal SLCS#.
3.13.3 GPIF and FIFO Clock Rates
An 8051 register bit selects one of two frequencies for the
internally supplied interface clock: 30 MHz and 48 MHz.
Alternatively, an externally supplied clock of 5 MHz–48 MHz
feeding the IFCLK pin can be used as the interface clock. IFCLK
can be configured to function as an output clock when the GPIF
and FIFOs are internally clocked. An output enable bit in the
IFCONFIG register turns this clock output off. Another bit within
the IFCONFIG register inverts the IFCLK signal whether
internally or externally sourced.
3.14 GPIF
The GPIF is a flexible 8- or 16-bit parallel interface driven by a
user programmable finite state machine. It allows the
CY7C68053 to perform local bus mastering, and can implement
a wide variety of protocols such as ATA interface, parallel printer
port, and Utopia.
The GPIF has three programmable control outputs (CTL), and
two general purpose ready inputs.The data bus width can be 8
or 16 bits. Each GPIF vector defines the state of the control
outputs, and determines what state a ready input (or multiple
inputs) must be before proceeding. The GPIF vector can be
programmed to advance a FIFO to the next data value, advance
an address, and so on. A sequence of the GPIF vectors makes
up a single waveform that is executed to perform the desired
data move between the FX2LP18 and the external device.
Note
5. Even though these buffers are 64 bytes, they are reported as 512 for USB 2.0 compliance. Nnever transfer packets larger than 64 bytes to EP1.
Document # 001-06120 Rev *I
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3.14.1 Three Control OUT Signals
3.16 USB Uploads and Downloads
The 56-pin package brings out three of these signals,
CTL0–CTL2. The 8051 programs the GPIF unit to define the CTL
waveforms. CTLx waveform edges can be programmed to make
transitions as fast as once per clock cycle (20.8 ns using a
48 MHz clock).
The core has the ability to directly edit the data contents of the
internal 16-kByte RAM and of the internal 512-byte scratch pad
RAM using a vendor-specific command. This capability is
normally used when ‘soft’ downloading user code and is
available only to and from internal RAM, only when the 8051 is
held in reset. The available RAM spaces are 16 kBytes from
0x0000–0x3FFF
(code/data)
and
512
bytes
from
0xE000–0xE1FF (scratch pad data RAM).[7]
3.14.2 Two Ready IN Signals
The FX2LP18 package brings out all two Ready inputs
(RDY0–RDY1). The 8051 programs the GPIF unit to test the
RDY pins for GPIF branching.
3.14.3 Long Transfer Mode
In master mode, the 8051 appropriately sets GPIF transaction
count registers (GPIFTCB3, GPIFTCB2, GPIFTCB1, or
GPIFTCB0) for unattended transfers of up to 232 transactions.
The GPIF automatically throttles data flow to prevent under or
overflow until the full number of requested transactions
complete. The GPIF decrements the value in these registers to
represent the current status of the transaction.
3.15 ECC
Generation[6]
The MoBL-USB can calculate Error Correcting Codes (ECCs) on
data that passes across its GPIF or Slave FIFO interfaces. There
are two ECC configurations: two ECCs, each calculated over
256 bytes (SmartMedia Standard) and one ECC calculated over
512 bytes.
The ECC can correct any 1-bit error or detect any 2-bit error.
3.15.1 ECC Implementation
The two ECC configurations are selected by the ECCM bit.
3.15.1.1 ECCM = 0
Two 3-byte ECCs are each calculated over a 256-byte block of
data. This configuration conforms to the SmartMedia Standard.
This configuration writes any value to ECCRESET, then passes
data across the GPIF or Slave FIFO interface. The ECC for the
first 256 bytes of data is calculated and stored in ECC1. The ECC
for the next 256 bytes is stored in ECC2. After the second ECC
is calculated, the values in the ECCx registers do not change
until ECCRESET is written again, even if more data is
subsequently passed across the interface.
3.15.1.2 ECCM = 1
One 3-byte ECC is calculated over a 512-byte block of data.
This configuration writes any value to ECCRESET then passes
data across the GPIF or Slave FIFO interface. The ECC for the
first 512 bytes of data is calculated and stored in ECC1; ECC2
is unused. After the ECC is calculated, the value in ECC1 does
not change until ECCRESET is written again, even if more data
is subsequently passed across the interface.
3.17 Autopointer Access
FX2LP18 provides two identical autopointers. They are similar to
the internal 8051 data pointers, but with an additional feature:
they can optionally increment after every memory access. The
autopointers are available in external FX2LP18 registers, under
control of a mode bit (AUTOPTRSET-UP.0). Using the external
FX2LP18 autopointer access (at 0xE67B – 0xE67C) allows the
autopointer to access all RAM. Also, the autopointers can point
to any FX2LP18 register or endpoint buffer space.
3.18 I2C Controller
FX2LP18 has one I2C port that is driven by two internal
controllers. One controller automatically operates at boot time to
load the VID/PID/DID, configuration byte, and firmware. The
second controller is used by the 8051, once running, to control
external I2C devices. The I2C port operates in master mode only.
3.18.1 I2C Port Pins
The I2C pins SCL and SDA must have external 2.2K ohm pull up
resistors even if no EEPROM is connected to the FX2LP18. The
value of the pull up resistors required may vary, depending on
the combination of VCC_IO and the supply used for the EEPROM.
The pull up resistors used must be such that when the EEPROM
pulls SDA low, the voltage level meets the VIL specification of the
FX2LP18. For example, if the EEPROM runs off a 3.3V supply
and VCC_IO is 1.8V, the pull up resistors recommended are 10K
ohm. This requirement may also vary depending on the devices
being run on the I2C pins. Refer to the I2C specifications for
details.
External EEPROM device address pins must be configured
properly. See Table 6 on page 10 for configuring the device
address pins.
If no EEPROM is connected to the I2C port, EEPROM emulation
is required by an external processor. This is because the
FX2LP18 comes out of reset with the DISCON bit set, so the
device will not enumerate without an EEPROM (C2 load) or
EEPROM emulation.
Notes
6. To use the ECC logic, the GPIF or Slave FIFO interface must be configured for byte-wide operation.
7. After the data is downloaded from the host, a ‘loader’ can execute from internal RAM in order to transfer downloaded data to external memory.
Document # 001-06120 Rev *I
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CY7C68053
Table 6. Strap Boot EEPROM Address Lines to These
Values
Bytes
Example EEPROM
16
24AA00
128
24AA01
[8]
A2
A1
A0
N/A
N/A
N/A
0
0
0
256
24AA02
0
0
0
4K
24AA32
0
0
1
8K
24AA64
0
0
1
16K
24AA128
0
0
1
program/data. The available RAM spaces are 16 kBytes from
0x0000–0x3FFF and 512 bytes from 0xE000–0xE1FF. The 8051
is reset. I2C interface boot loads only occur after power on reset.
3.18.3 I2C Interface General Purpose Access
The 8051 can control peripherals connected to the I2C bus using
the I2CTL and I2DAT registers. FX2LP18 provides I2C master
control only, it is never an I2C slave.
4. Pin Assignments
3.18.2 I2C Interface Boot Load Access
At power on reset the I2C interface boot loader loads the
VID/PID/DID and configuration bytes and up to 16 kBytes of
Figure 6 identifies all signals for the package. It is followed by the
pin diagram.Three modes are available: Port, GPIF master, and
Slave FIFO. These modes define the signals on the right edge
of the diagram. The 8051 selects the interface mode using the
IFCONFIG[1:0] register bits. Port mode is the power on default
configuration.
Figure 6. Signals
Port
XTALIN
XTALOUT
RESET#
WAKEUP#
SCL
SDA
IFCLK
CLKOUT
DPLUS
DMINUS
GPIF Master
PD7
PD6
PD5
PD4
PD3
PD2
PD1
PD0
PB7
PB6
PB5
PB4
PB3
PB2
PB1
PB0
INT0#/PA0
INT1#/PA1
PA2
WU2/PA3
PA4
PA5
PA6
PA7
FD[15]
FD[14]
FD[13]
FD[12]
FD[11]
FD[10]
FD[9]
FD[8]
FD[7]
FD[6]
FD[5]
FD[4]
FD[3]
FD[2]
FD[1]
FD[0]
Slave FIFO
FD[15]
FD[14]
FD[13]
FD[12]
FD[11]
FD[10]
FD[9]
FD[8]
FD[7]
FD[6]
FD[5]
FD[4]
FD[3]
FD[2]
FD[1]
FD[0]
RDY0
RDY1
SLRD
SLWR
CTL0
CTL1
CTL2
FLAGA
FLAGB
FLAGC
INT0#/PA0
INT1#/PA1
PA2
WU2/PA3
PA4
PA5
PA6
PA7
INT0#/PA0
INT1#/PA1
SLOE
WU2/PA3
FIFOADR0
FIFOADR1
PKTEND
PA7/FLAGD/SLCS#
Note
8. This EEPROM does not have address pins.
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Figure 7. CY7C68053 56-pin VFBGA Pin Assignment - Top View
1
2
3
4
5
6
7
8
A
1A
2A
3A
4A
5A
6A
7A
8A
B
1B
2B
3B
4B
5B
6B
7B
8B
C
1C
2C
3C
4C
5C
6C
7C
8C
D
1D
2D
7D
8D
E
1E
2E
7E
8E
F
1F
2F
3F
4F
5F
6F
7F
8F
G
1G
2G
3G
4G
5G
6G
7G
8G
H
1H
2H
3H
4H
5H
6H
7H
8H
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CY7C68053
4.1 CY7C68053 Pin Descriptions
Table 7. FX2LP18 Pin Descriptions [9]
56 VFBGA
Name
Type
Default
Description
2D
AVCC
Power
N/A
Analog VCC. Connect this pin to 3.3V power source. This signal provides
power to the analog section of the chip.
Provide an appropriate bulk/bypass capacitance for this supply rail.
1D
AVCC
Power
N/A
Analog VCC. Connect this pin to 3.3V power source. This signal provides
power to the analog section of the chip.
2F
AGND
Ground
N/A
Analog Ground. Connect this pin to ground with as short a path as possible.
1F
AGND
Ground
N/A
1E
DMINUS
I/O/Z
Z
USB D– Signal. Connect this pin to the USB D– signal.
USB D+ Signal. Connect this pin to the USB D+ signal.
Analog Ground. Connect to this pin ground with as short a path as possible.
2E
DPLUS
I/O/Z
Z
8B
RESET#
Input
N/A
Active LOW Reset. This pin resets the entire chip. See Reset and Wakeup on
page 5 for details.
1C
XTALIN
Input
N/A
Crystal Input. Connect this signal to a 24 MHz parallel resonant, fundamental
mode crystal and load capacitor to GND.
It is also correct to drive XTALIN with an external 24 MHz square wave derived
from another clock source.
2C
XTALOUT
Output
N/A
Crystal Output. Connect this signal to a 24 MHz parallel resonant, fundamental mode crystal and load capacitor to GND.
If an external clock is used to drive XTALIN, leave this pin open.
2B
CLKOUT
O/Z
12 MHz
CLKOUT. 12, 24, or 48 MHz clock, phase locked to the 24 MHz input clock.
The 8051 defaults to 12 MHz operation. The 8051 may tri-state this output by
setting CPUCS.1 = 1.
8G
PA0 or
INT0#
I/O/Z
I
(PA0)
Multiplexed pin whose function is selected by PORTACFG.0
PA0 is a bidirectional I/O port pin.
INT0# is the active LOW 8051 INT0 interrupt input signal, which is either edge
triggered (IT0 = 1) or level triggered (IT0 = 0).
6G
PA1 or
INT1#
I/O/Z
I
(PA1)
Multiplexed pin whose function is selected by PORTACFG.1
PA1 is a bidirectional I/O port pin.
INT1# is the active LOW 8051 INT1 interrupt input signal, which is either edge
triggered (IT1 = 1) or level triggered (IT1 = 0).
8F
PA2 or
SLOE
I/O/Z
I
(PA2)
Multiplexed pin whose function is selected by two bits: IFCONFIG[1:0].
PA2 is a bidirectional I/O port pin.
SLOE is an input-only output enable with programmable polarity (FIFOPINPOLAR.4) for the slave FIFO’s connected to FD[7:0] or FD[15:0].
7F
PA3 or
WU2
I/O/Z
I
(PA3)
Multiplexed pin whose function is selected by: WAKEUP.7 and OEA.3
PA3 is a bidirectional I/O port pin.
WU2 is an alternate source for USB Wakeup, enabled by WU2EN bit
(WAKEUP.1) and polarity set by WU2POL (WAKEUP.4). If the 8051 is in
suspend and WU2EN = 1, a transition on this pin starts up the oscillator and
interrupts the 8051 to allow it to exit the suspend mode. Asserting this pin
inhibits the chip from suspending, if WU2EN = 1.
Port A
Note
9. Do not leave unused inputs floating. Tie either HIGH or LOW as appropriate. Only pull outputs up or down to ensure signals at power up and in standby. Do not drive
any pins while the device is powered down.
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Table 7. FX2LP18 Pin Descriptions (continued)[9]
56 VFBGA
Name
Type
Default
Description
6F
PA4 or
FIFOADR0
I/O/Z
I
(PA4)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PA4 is a bidirectional I/O port pin.
FIFOADR0 is an input-only address select for the slave FIFOs connected to
FD[7:0] or FD[15:0].
8C
PA5 or
FIFOADR1
I/O/Z
I
(PA5)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PA5 is a bidirectional I/O port pin.
FIFOADR1 is an input-only address select for the slave FIFOs connected to
FD[7:0] or FD[15:0].
7C
PA6 or
PKTEND
I/O/Z
I
(PA6)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] bits.
PA6 is a bidirectional I/O port pin.
PKTEND is an input that commits the FIFO packet data to the endpoint and
whose polarity is programmable using FIFOPINPOLAR.5.
6C
PA7 or
FLAGD or
SLCS#
I/O/Z
I
(PA7)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
PORTACFG.7 bits.
PA7 is a bidirectional I/O port pin.
FLAGD is a programmable slave FIFO output status flag signal.
SLCS# gates all other slave FIFO enable/strobes
3H
PB0 or
FD[0]
I/O/Z
I
(PB0)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB0 is a bidirectional I/O port pin.
FD[0] is the bidirectional FIFO/GPIF data bus.
4F
PB1 or
FD[1]
I/O/Z
I
(PB1)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB1 is a bidirectional I/O port pin.
FD[1] is the bidirectional FIFO/GPIF data bus.
4H
PB2 or
FD[2]
I/O/Z
I
(PB2)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB2 is a bidirectional I/O port pin.
FD[2] is the bidirectional FIFO/GPIF data bus.
4G
PB3 or
FD[3]
I/O/Z
I
(PB3)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB3 is a bidirectional I/O port pin.
FD[3] is the bidirectional FIFO/GPIF data bus.
5H
PB4 or
FD[4]
I/O/Z
I
(PB4)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB4 is a bidirectional I/O port pin.
FD[4] is the bidirectional FIFO/GPIF data bus.
5G
PB5 or
FD[5]
I/O/Z
I
(PB5)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB5 is a bidirectional I/O port pin.
FD[5] is the bidirectional FIFO/GPIF data bus.
5F
PB6 or
FD[6]
I/O/Z
I
(PB6)
Multiplexed pin whose function is selected by IFCONFIG[1:0].
PB6 is a bidirectional I/O port pin.
FD[6] is the bidirectional FIFO/GPIF data bus.
6H
PB7 or
FD[7]
I/O/Z
I
(PB7)
Multiplexed pin whose function is selected IFCONFIG[1:0].
PB7 is a bidirectional I/O port pin.
FD[7] is the bidirectional FIFO/GPIF data bus.
Port B
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Table 7. FX2LP18 Pin Descriptions (continued)[9]
56 VFBGA
Name
Type
Default
Description
PORT D
8A
PD0 or
FD[8]
I/O/Z
I
(PD0)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[8] is the bidirectional FIFO/GPIF data bus.
7A
PD1 or
FD[9]
I/O/Z
I
(PD1)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[9] is the bidirectional FIFO/GPIF data bus.
6B
PD2 or
FD[10]
I/O/Z
I
(PD2)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[10] is the bidirectional FIFO/GPIF data bus.
6A
PD3 or
FD[11]
I/O/Z
I
(PD3)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[11] is the bidirectional FIFO/GPIF data bus.
3B
PD4 or
FD[12]
I/O/Z
I
(PD4)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[12] is the bidirectional FIFO/GPIF data bus.
3A
PD5 or
FD[13]
I/O/Z
I
(PD5)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[13] is the bidirectional FIFO/GPIF data bus.
3C
PD6 or
FD[14]
I/O/Z
I
(PD6)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[14] is the bidirectional FIFO/GPIF data bus.
2A
PD7 or
FD[15]
I/O/Z
I
(PD7)
Multiplexed pin whose function is selected by the IFCONFIG[1:0] and
EPxFIFOCFG.0 (wordwide) bits.
FD[15] is the bidirectional FIFO/GPIF data bus.
1A
RDY0 or
SLRD
Input
N/A
Multiplexed pin whose function is selected by IFCONFIG[1:0].
RDY0 is a GPIF input signal.
SLRD is the input only read strobe with programmable polarity (FIFOPINPOLAR.3) for the slave FIFOs connected to FD[7:0] or FD[15:0].
1B
RDY1 or
SLWR
Input
N/A
Multiplexed pin whose function is selected by IFCONFIG[1:0].
RDY1 is a GPIF input signal.
SLWR is the input only write strobe with programmable polarity (FIFOPINPOLAR.2) for the slave FIFOs connected to FD[7:0] or FD[15:0].
7H
CTL0 or
FLAGA
O/Z
H
Multiplexed pin whose function is selected by IFCONFIG[1:0].
CTL0 is a GPIF control output.
FLAGA is a programmable slave FIFO output status flag signal.
Defaults to programmable for the FIFO selected by the FIFOADR[1:0] pins.
7G
CTL1 or
FLAGB
O/Z
H
Multiplexed pin whose function is selected by IFCONFIG[1:0].
CTL1 is a GPIF control output.
FLAGB is a programmable slave FIFO output status flag signal.
Defaults to FULL for the FIFO selected by the FIFOADR[1:0] pins.
8H
CTL2 or
FLAGC
O/Z
H
Multiplexed pin whose function is selected IFCONFIG[1:0].
CTL2 is a GPIF control output.
FLAGC is a programmable slave FIFO output status flag signal.
Defaults to EMPTY for the FIFO selected by the FIFOADR[1:0] pins.
2G
IFCLK
I/O/Z
Z
Interface clock, used to synchronous clock data into or out of the slave FIFOs.
IFCLK also serves as a timing reference for all slave FIFO control signals and
GPIF. When internal clocking is used (IFCONFIG.7 = 1) the IFCLK pin can be
configured to output 30 or 48 MHz by bits IFCONFIG.5 and IFCONFIG.6. IFCLK
may be inverted, whether internally or externally sourced, by setting the bit
IFCONFIG.4 =1.
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Table 7. FX2LP18 Pin Descriptions (continued)[9]
56 VFBGA
Name
Type
Default
Description
7B
WAKEUP
Input
N/A
USB Wakeup. If the 8051 is in suspend, asserting this pin starts up the oscillator and interrupts the 8051 to allow it to exit the suspend mode. Holding
WAKEUP asserted inhibits the MoBL-USB® chip from suspending. This pin
has programmable polarity (WAKEUP.4).
3F
SCL
OD
Z
Clock for the I2C interface. Connect to VCC_IO or VCC with a 2.2K–10K pull up
resistor. (An I2C peripheral is required.)
3G
SDA
OD
Z
Data for the I2C interface. Connect to VCC_IO or VCC with a 2.2K–10K pull up
resistor. (An I2C peripheral is required.)
5A
VCC_IO
Power
N/A
VCC. Connect this pin to 1.8V to 3.3V power source.
Provide the appropriate bulk and bypass capacitance for this supply rail.
5B
VCC_IO
Power
N/A
VCC. Connect this pin to 1.8V to 3.3V power source.
7E
VCC_IO
Power
N/A
VCC. Connect this pin to 1.8V to 3.3V power source.
8E
VCC_IO
Power
N/A
VCC. Connect this pin to 1.8V to 3.3V power source.
5C
VCC_D
Power
N/A
VCC. Connect this pin to 1.8V power source. (Supplies power to internal digital
1.8V circuits.)
Provide the appropriate bulk and bypass capacitance for this supply rail.
1G
VCC_A
Power
N/A
VCC. Connect this pin to 1.8V power source. (Supplies power to internal analog
1.8V circuits.)
1H
GND
Ground
N/A
Ground.
2H
GND
Ground
N/A
Ground.
4A
GND
Ground
N/A
Ground.
4B
GND
Ground
N/A
Ground.
4C
GND
Ground
N/A
Ground.
7D
GND
Ground
N/A
Ground.
8D
GND
Ground
N/A
Ground.
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5. Register Summary
FX2LP18 register bit definitions are described in the MoBL-USB FX2LP18 TRM in greater detail.
Table 8. FX2LP18 Register Summary
Hex
E400
E480
E50D
E600
E601
E602
E603
E604
E605
E606
E607
E608
E609
E60A
Size Name
Description
GPIF Waveform Memories
128 WAVEDATA
GPIF Waveform
descriptor 0, 1, 2, 3 data
128 Reserved
GENERAL CONFIGURATION
GPCR2
General Purpose Configuration Register 2
1 CPUCS
CPU Control and Status
1 IFCONFIG
Interface Configuration
(Ports, GPIF, Slave FIFOs)
[10]
1 PINFLAGSAB
Slave FIFO FLAGA and
FLAGB pin configuration
1 PINFLAGSCD[10]
Slave FIFO FLAGC and
FLAGD pin configuration
1 FIFORESET[10]
Restore FIFOs to default
state
1 BREAKPT
Breakpoint control
1 BPADDRH
Breakpoint address H
1 BPADDRL
Breakpoint address L
1 Reserved
Reserved
1 FIFOPINPOLAR[10] Slave FIFO interface pins
polarity
1 REVID
Chip revision
E60B
1
E60C
1
3
E610
1
E611
1
E612
E613
E614
E615
E618
1
1
1
1
2
1
E619
1
E61A
1
E61B
1
E61C
E620
4
1
E621
1
E622
1
E623
1
E624
1
E625
1
E626
1
E627
1
E628
E629
E62A
E62B
1
1
1
1
REVCTL[10]
Chip revision control
UDMA
GPIFHOLDAMOUNT MSTB hold time
(for UDMA)
Reserved
ENDPOINT CONFIGURATION
EP1OUTCFG
Endpoint 1-OUT
configuration
EP1INCFG
Endpoint 1-IN
configuration
EP2CFG
Endpoint 2 configuration
EP4CFG
Endpoint 4 configuration
EP6CFG
Endpoint 6 configuration
EP8CFG
Endpoint 8 configuration
Reserved
EP2FIFOCFG[10]
Endpoint 2/Slave FIFO
configuration
[10]
EP4FIFOCFG
Endpoint 4/Slave FIFO
configuration
EP6FIFOCFG[10]
Endpoint 6/Slave FIFO
configuration
[10]
EP8FIFOCFG
Endpoint 8/Slave FIFO
configuration
Reserved
EP2AUTOINLENH[10 Endpoint 2 AUTOIN
packet length H
EP2AUTOINLENL[10] Endpoint 2 AUTOIN
packet length L
EP4AUTOINLENH[10 Endpoint 4 AUTOIN
]
packet length H
EP4AUTOINLENL[10] Endpoint 4 AUTOIN
packet length L
EP6AUTOINLENH[10 Endpoint 6 AUTOIN
]
packet length H
EP6AUTOINLENL[10] Endpoint 6 AUTOIN
packet length L
EP8AUTOINLENH[10 Endpoint 8 AUTOIN
]
packet length H
EP8AUTOINLENL[10] Endpoint 8 AUTOIN
packet length L
ECCCFG
ECC Configuration
ECCRESET
ECC Reset
ECC1B0
ECC1 Byte 0 address
ECC1B1
ECC1 Byte 1 address
b7
b6
b5
b4
b3
b2
b1
b0
Default
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
00000000 R
0
IFCLKSRC
0
3048MHZ
CLKINV
GSTATE
CLKOE
IFCFG1
8051RES
IFCFG0
00000010 rrbbbbbr
10000000 RW
FULL_SPEED Reserved
_ONLY
PORTCSTB CLKSPD1
CLKSPD0
IFCLKOE
IFCLKPOL
ASYNC
Access
FLAGB3
FLAGB2
FLAGB1
FLAGB0
FLAGA3
FLAGA2
FLAGA1
FLAGA0
00000000 RW
FLAGD3
FLAGD2
FLAGD1
FLAGD0
FLAGC3
FLAGC2
FLAGC1
FLAGC0
00000000 RW
NAKALL
0
0
0
EP3
EP2
EP1
EP0
0
A15
A7
0
0
0
A14
A6
0
0
0
A13
A5
0
PKTEND
0
A12
A4
0
SLOE
BREAK
A11
A3
0
SLRD
BPPULSE
A10
A2
0
SLWR
BPEN
A9
A1
0
EF
0
A8
A0
0
FF
00000000 rrrrbbbr
xxxxxxxx RW
xxxxxxxx RW
00000000 rrrrrrbb
00000000 rrbbbbbb
rv7
rv6
rv5
rv4
rv3
rv2
rv1
rv0
0
0
0
0
0
0
dyn_out
enh_pkt
RevA
R
00000001
00000000 rrrrrrbb
0
0
0
0
0
0
VALID
0
TYPE1
TYPE0
0
0
0
0
10100000 brbbrrrr
VALID
0
TYPE1
TYPE0
0
0
0
0
10100000 brbbrrrr
VALID
VALID
VALID
VALID
DIR
DIR
DIR
DIR
TYPE1
TYPE1
TYPE1
TYPE1
TYPE0
TYPE0
TYPE0
TYPE0
SIZE
0
SIZE
0
0
0
0
0
BUF1
0
BUF1
0
BUF0
0
BUF0
0
0
INFM1
OEP1
AUTOOUT
AUTOIN
ZEROLENIN
0
WORDWIDE 00000101 rbbbbbrb
0
INFM1
OEP1
AUTOOUT
AUTOIN
ZEROLENIN
0
WORDWIDE 00000101 rbbbbbrb
0
INFM1
OEP1
AUTOOUT
AUTOIN
ZEROLENIN
0
WORDWIDE 00000101 rbbbbbrb
0
INFM1
OEP1
AUTOOUT
AUTOIN
ZEROLENIN
0
WORDWIDE 00000101 rbbbbbrb
0
0
0
0
0
PL10
PL9
PL8
00000010 rrrrrbbb
PL7
PL6
PL5
PL4
PL3
PL2
PL1
PL0
00000000 RW
xxxxxxxx W
HOLDTIME1 HOLDTIME0 00000000 rrrrrrbb
10100010 bbbbbrbb
10100000 bbbbrrrr
11100010 bbbbbrbb
11100000 bbbbrrrr
0
0
0
0
0
0
PL9
PL8
00000010 rrrrrrbb
PL7
PL6
PL5
PL4
PL3
PL2
PL1
PL0
00000000 RW
0
0
0
0
0
PL10
PL9
PL8
00000010 rrrrrbbb
PL7
PL6
PL5
PL4
PL3
PL2
PL1
PL0
00000000 RW
0
0
0
0
0
0
PL9
PL8
00000010 rrrrrrbb
PL7
PL6
PL5
PL4
PL3
PL2
PL1
PL0
00000000 RW
0
x
LINE15
LINE7
0
x
LINE14
LINE6
0
x
LINE13
LINE5
0
x
LINE12
LINE4
0
x
LINE11
LINE3
0
x
LINE10
LINE2
0
x
LINE9
LINE1
ECCM
x
LINE8
LINE0
00000000 rrrrrrrb
00000000 W
00000000 R
00000000 R
Note
10. Read and writes to these registers may require synchronization delay, see MoBL-USB FX2LP18 Technical Reference Manual for ‘Synchronization Delay.’
Document # 001-06120 Rev *I
Page 16 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex Size Name
E62C 1 ECC1B2
E62D 1 ECC2B0
E62E 1 ECC2B1
Description
ECC1 Byte 2 address
ECC2 Byte 0 address
ECC2 Byte 1 address
b7
COL5
LINE15
LINE7
b6
COL4
LINE14
LINE6
b5
COL3
LINE13
LINE5
E62F
E630
H.S.
E630
F.S.
E631
H.S.
E631
F.S
E632
H.S.
E632
F.S
E633
H.S.
E633
F.S
ECC2 Byte 2 address
Endpoint 2/Slave FIFO
programmable flag H
Endpoint 2/Slave FIFO
programmable flag H
Endpoint 2/Slave FIFO
programmable flag L
Endpoint 2/Slave FIFO
programmable flag L
Endpoint 4/Slave FIFO
programmable flag H
Endpoint 4/Slave FIFO
programmable flag H
Endpoint 4/Slave FIFO
programmable flag L
Endpoint 4/Slave FIFO
programmable flag L
COL5
DECIS
COL4
PKTSTAT
DECIS
PKTSTAT
COL3
IN:PKTS[2]
OUT:PFC12
OUT:PFC12
PFC7
PFC6
PFC5
PFC4
PFC3
IN:PKTS[1]
OUT:PFC7
DECIS
IN:PKTS[0]
OUT:PFC6
PKTSTAT
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
0
0
PFC8
10001000 bbrbbrrb
PKTSTAT
0
IN: PKTS[0]
OUT:PFC9
OUT:PFC9
0
DECIS
IN: PKTS[1]
OUT:PFC10
OUT:PFC10
0
0
PFC8
10001000 bbrbbrrb
PFC7
PFC6
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
IN: PKTS[1]
OUT:PFC7
IN: PKTS[0]
OUT:PFC6
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
DECIS
PKTSTAT
0
PFC9
PFC8
00001000 bbbbbrbb
DECIS
PKTSTAT
IN:PKTS[2]
OUT:PFC12
OUT:PFC12
0
PFC9
PFC7
PFC6
PFC5
PFC4
PFC3
PFC2
PFC1
IN:PKTS[1]
OUT:PFC7
DECIS
IN:PKTS[0]
OUT:PFC6
PKTSTAT
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
0
0
PFC8
00001000 bbrbbrrb
PKTSTAT
0
IN: PKTS[0]
OUT:PFC9
OUT:PFC9
0
DECIS
IN: PKTS[1]
OUT:PFC10
OUT:PFC10
0
0
PFC8
00001000 bbrbbrrb
PFC7
PFC6
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
IN: PKTS[1]
OUT:PFC7
IN: PKTS[0]
OUT:PFC6
PFC5
PFC4
PFC3
PFC2
PFC1
PFC0
00000000 RW
AADJ
0
0
0
0
0
INPPF1
INPPF0
00000001 brrrrrbb
AADJ
0
0
0
0
0
INPPF1
INPPF0
00000001 brrrrrrr
AADJ
0
0
0
0
0
INPPF1
INPPF0
00000001 brrrrrbb
AADJ
0
0
0
0
0
INPPF1
INPPF0
00000001 brrrrrrr
Skip
Skip
0
0
0
0
0
0
EP3
EP3
EP2
EP2
EP1
EP1
EP0
EP0
0
0
0
0
EDGEPF
PF
EF
FF
00000000 RW
0
0
0
0
0
PF
EF
FF
00000000 rrrrrbbb
0
0
0
0
EDGEPF
PF
EF
FF
00000000 RW
0
0
0
0
0
PF
EF
FF
00000000 rrrrrbbb
0
0
0
0
EDGEPF
PF
EF
FF
00000000 RW
0
0
0
0
0
PF
EF
FF
00000000 rrrrrbbb
0
0
0
0
EDGEPF
PF
EF
FF
00000000 RW
0
0
0
0
0
PF
EF
FF
00000000 rrrrrbbb
0
0
EP8
EP6
EP4
EP2
EP1
EP0
00000000 RW
0
0
EP8
EP6
EP4
EP2
EP1
EP0
00xxxxxx rrbbbbbb
EP8
EP6
EP4
EP2
EP1
EP0
0
IBN
00000000 RW
EP8
EP6
EP4
EP2
EP1
EP0
0
IBN
xxxxxx0x bbbbbbrb
0
0
EP0ACK
EP0ACK
HSGRANT
HSGRANT
URES
URES
SUSP
SUSP
SUTOK
SUTOK
SOF
SOF
SUDAV
SUDAV
00000000 RW
0xxxxxxx rbbbbbbb
1
1
ECC2B2
EP2FIFOPFH[10]
1
EP2FIFOPFH[10]
1
EP2FIFOPFL[10]
1
EP2FIFOPFL[10]
1
EP4FIFOPFH[10]
1
EP4FIFOPFH[10]
1
EP4FIFOPFL[10]
1
EP4FIFOPFL[10]
1
EP6FIFOPFH[10]
1
EP6FIFOPFH[10]
1
EP6FIFOPFL[10]
1
EP6FIFOPFL[10]
1
EP8FIFOPFH[10]
1
EP8FIFOPFH[10]
1
EP8FIFOPFL[10]
1
EP8FIFOPFL[10]
E640
8
1
Reserved
EP2ISOINPKTS
E641
1
EP4ISOINPKTS
E642
1
EP6ISOINPKTS
E643
1
EP8ISOINPKTS
E644
E648
E649
4
1
7
E650
1
Reserved
INPKTEND[10]
OUTPKTEND[10]
INTERRUPTS
EP2FIFOIE[10]
E634
H.S.
E634
F.S
E635
H.S.
E635
F.S
E636
H.S.
E636
F.S
E637
H.S.
E637
F.S
E651
1
EP2FIFOIRQ
[10,11]
[10]
E652
1
EP4FIFOIE
E653
1
EP4FIFOIRQ[10,11]
E654
1
EP6FIFOIE[10]
E655
1
EP6FIFOIRQ
[10,11]
[10]
E656
1
EP8FIFOIE
E657
1
EP8FIFOIRQ[10,11]
E658
1
IBNIE
E659
1
IBNIRQ[11]
E65A
1
NAKIE
E65B
1
NAKIRQ[11]
E65C
E65D
1
1
USBIE
USBIRQ[11]
Endpoint 6/Slave FIFO
programmable flag H
Endpoint 6/Slave FIFO
programmable flag H
Endpoint 6/Slave FIFO
programmable flag L
Endpoint 6/Slave FIFO
programmable flag L
Endpoint 8/Slave FIFO
programmable flag H
Endpoint 8/Slave FIFO
programmable flag H
Endpoint 8/Slave FIFO
programmable flag L
Endpoint 8/Slave FIFO
programmable flag L
EP2 (if ISO) IN packets per
frame (1-3)
EP4 (if ISO) IN packets per
frame (1-3)
EP6 (if ISO) IN packets per
frame (1-3)
EP8 (if ISO) IN packets per
frame (1-3)
Force IN packet end
Force OUT packet end
Endpoint 2 Slave FIFO flag
interrupt enable
Endpoint 2 Slave FIFO flag
interrupt request
Endpoint 4 Slave FIFO flag
interrupt enable
Endpoint 4 Slave FIFO flag
interrupt request
Endpoint 6 Slave FIFO flag
interrupt enable
Endpoint 6 Slave FIFO flag
interrupt request
Endpoint 8 Slave FIFO flag
interrupt enable
Endpoint 8 Slave FIFO flag
interrupt request
IN-BULK-NAK interrupt
enable
IN-BULK-NAK interrupt
request
Endpoint Ping-NAK/IBN
interrupt enable
Endpoint Ping-NAK/IBN
interrupt request
USB interrupt enables
USB interrupt requests
b4
COL2
LINE12
LINE4
b3
COL1
LINE11
LINE3
COL2
COL1
IN:PKTS[1] IN:PKTS[0]
OUT:PFC11 OUT:PFC10
OUT:PFC11 OUT:PFC10
IN:PKTS[1] IN:PKTS[0]
OUT:PFC11 OUT:PFC10
OUT:PFC11 OUT:PFC10
b2
COL0
LINE10
LINE2
b1
LINE17
LINE9
LINE1
b0
LINE16
LINE8
LINE0
COL0
0
0
PFC9
0
PFC8
0
PFC9
PFC2
PFC1
Default Access
00000000 R
00000000 R
00000000 R
00000000 R
10001000 bbbbbrbb
IN:PKTS[2] 10001000 bbbbbrbb
OUT:PFC8
PFC0
00000000 RW
IN:PKTS[2] 00001000 bbbbbrbb
OUT:PFC8
PFC0
00000000 RW
xxxxxxxx W
xxxxxxxx W
Note
11. The register can only be reset, it cannot be set.
Document # 001-06120 Rev *I
Page 17 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex Size Name
E65E 1 EPIE
E65F
1
EPIRQ[11]
E660
E661
E662
1
1
1
GPIFIE[10]
GPIFIRQ[10]
USBERRIE
E663
1
USBERRIRQ[11]
E664
E665
E666
1
1
1
ERRCNTLIM
CLRERRCNT
INT2IVEC
E667
E668
E669
1
1
7
E670
1
Reserved
INTSET-UP
Reserved
INPUT/OUTPUT
PORTACFG
E671
1
PORTCCFG
E672
1
PORTECFG
E673
E677
E678
E679
E67A
E67B
4
1
1
1
1
1
Reserved
Reserved
I2CS
I2DAT
I2CTL
XAUTODAT1
E67C
1
XAUTODAT2
E67D
E67E
E67F
1
1
1
E680
E681
E682
E683
E684
E685
E686
E687
E688
1
1
1
1
1
1
1
1
2
E68A
E68B
E68C
E68D
E68E
E68F
E690
E691
E692
E694
E695
E696
E698
E699
E69A
E69C
E69D
E69E
E6A0
1
1
1
1
1
1
1
1
2
1
1
2
1
1
2
1
1
2
1
UDMA CRC
UDMACRCH[10]
UDMACRCL[10]
UDMACRCQUALIFIER
USB CONTROL
USBCS
SUSPEND
WAKEUPCS
TOGCTL
USBFRAMEH
USBFRAMEL
MICROFRAME
FNADDR
Reserved
ENDPOINTS
EP0BCH[10]
EP0BCL[10]
Reserved
EP1OUTBC
Reserved
EP1INBC
EP2BCH[10]
EP2BCL[10]
Reserved
EP4BCH[10]
EP4BCL[10]
Reserved
EP6BCH[10]
EP6BCL[10]
Reserved
EP8BCH[10]
EP8BCL[10]
Reserved
EP0CS
E6A1
1
EP1OUTCS
Description
Endpoint interrupt
enables
Endpoint interrupt
requests
GPIF interrupt enable
GPIF interrupt request
USB error interrupt
enables
USB error interrupt
requests
USB error counter and limit
Clear error counter EC3:0
Interrupt 2 (USB)
autovector
Interrupt 2 and 4 setup
b7
EP8
b6
EP6
b5
EP4
b4
EP2
b3
EP1OUT
b2
EP1IN
b1
EP0OUT
b0
EP0IN
Default Access
00000000 RW
EP8
EP6
EP4
EP2
EP1OUT
EP1IN
EP0OUT
0
0
ISOEP8
0
0
ISOEP6
0
0
ISOEP4
0
0
ISOEP2
0
0
0
0
0
0
GPIFWF
GPIFWF
0
EP0IN
0
ISOEP8
ISOEP6
ISOEP4
ISOEP2
0
0
0
EC3
x
0
EC2
x
I2V4
EC1
x
I2V3
EC0
x
I2V2
LIMIT3
x
I2V1
LIMIT2
x
I2V0
LIMIT1
x
0
LIMIT0
x
0
xxxx0100 rrrrbbbb
xxxxxxxx W
00000000 R
1
0
0
0
0
0
0
0
0
AV2EN
0
0
0
Reserved
0
AV4EN
10000000 R
00000000 RW
RW
GPIFDONE 00000000 RW
GPIFDONE 000000xx RW
ERRLIMIT 00000000 RW
ERRLIMIT 0000000x bbbbrrrb
I/O PORTA alternate
configuration
FLAGD
SLCS
0
0
0
0
INT1
INT0
00000000 RW
I/O PORTC alternate
configuration
I/O PORTE alternate
configuration
GPIFA7
GPIFA6
GPIFA5
GPIFA4
GPIFA3
GPIFA2
GPIFA1
GPIFA0
00000000 RW
GPIFA8
T2EX
INT6
RXD1OUT
RXD0OUT
T2OUT
T1OUT
T0OUT
00000000 RW
I²C bus control and status
I²C bus data
I²C bus control
Autoptr1 MOVX access,
when APTREN = 1
Autoptr2 MOVX access,
when APTREN = 1
START
d7
0
D7
STOP
d6
0
D6
LASTRD
d5
0
D5
ID1
d4
0
D4
ID0
d3
0
D3
BERR
d2
0
D2
ACK
d1
STOPIE
D1
DONE
d0
400KHZ
D0
000xx000 bbbrrrrr
xxxxxxxx RW
00000000 RW
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
CRC15
CRC7
QENABLE
CRC14
CRC6
0
CRC13
CRC5
0
CRC12
CRC4
0
CRC11
CRC3
QSTATE
CRC10
CRC2
QSIGNAL2
CRC9
CRC1
QSIGNAL1
HSM
x
WU2
Q
0
FC7
0
0
0
x
WU
S
0
FC6
0
FA6
0
x
WU2POL
R
0
FC5
0
FA5
0
x
WUPOL
I/O
0
FC4
0
FA4
DISCON
x
0
EP3
0
FC3
0
FA3
NOSYNSOF
x
DPEN
EP2
FC10
FC2
MF2
FA2
RENUM
x
WU2EN
EP1
FC9
FC1
MF1
FA1
SIGRSUME
x
WUEN
EP0
FC8
FC0
MF0
FA0
(BC15)
(BC7)
(BC14)
BC6
(BC13)
BC5
(BC12)
BC4
(BC11)
BC3
(BC10)
BC2
(BC9)
BC1
(BC8)
BC0
xxxxxxxx RW
xxxxxxxx RW
0
BC6
BC5
BC4
BC3
BC2
BC1
BC0
0xxxxxxx RW
Endpoint 1 IN byte count
Endpoint 2 byte count H
Endpoint 2 byte count L
0
0
BC7/SKIP
BC6
0
BC6
BC5
0
BC5
BC4
0
BC4
BC3
0
BC3
BC2
BC10
BC2
BC1
BC9
BC1
BC0
BC8
BC0
0xxxxxxx RW
00000xxx RW
xxxxxxxx RW
Endpoint 4 byte count H
Endpoint 4 byte count L
0
BC7/SKIP
0
BC6
0
BC5
0
BC4
0
BC3
0
BC2
BC9
BC1
BC8
BC0
000000xx RW
xxxxxxxx RW
Endpoint 6 byte count H
Endpoint 6 byte count L
0
BC7/SKIP
0
BC6
0
BC5
0
BC4
0
BC3
BC10
BC2
BC9
BC1
BC8
BC0
00000xxx RW
xxxxxxxx RW
Endpoint 8 byte count H
Endpoint 8 byte count L
0
BC7/SKIP
0
BC6
0
BC5
0
BC4
0
BC3
0
BC2
BC9
BC1
BC8
BC0
000000xx RW
xxxxxxxx RW
HSNAK
0
0
0
0
0
BUSY
STALL
10000000 bbbbbbrb
0
0
0
0
0
0
BUSY
STALL
00000000 bbbbbbrb
UDMA CRC MSB
UDMA CRC LSB
UDMA CRC qualifier
USB control and status
Put chip into suspend
Wakeup control and status
Toggle control
USB frame count H
USB frame count L
Microframe count, 0-7
USB function address
Endpoint 0 byte count H
Endpoint 0 byte count L
Endpoint 1 OUT byte count
Endpoint 0 control and
status
Endpoint 1 OUT control and
status
Document # 001-06120 Rev *I
xxxxxxxx RW
CRC8
01001010 RW
CRC0
10111010 RW
QSIGNAL0 00000000 brrrbbbb
x0000000 rrrrbbbb
xxxxxxxx W
xx000101 bbbbrbbb
x0000000 rrrbbbbb
00000xxx R
xxxxxxxx R
00000xxx R
0xxxxxxx R
Page 18 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex Size Name
E6A2 1 EP1INCS
E6A3
1
EP2CS
E6A4
1
EP4CS
E6A5
1
EP6CS
E6A6
1
EP8CS
E6A7
E6A8
E6A9
E6AA
E6AB
1
1
1
1
1
EP2FIFOFLGS
EP4FIFOFLGS
EP6FIFOFLGS
EP8FIFOFLGS
EP2FIFOBCH
E6AC
1
EP2FIFOBCL
E6AD
1
EP4FIFOBCH
E6AE
1
EP4FIFOBCL
E6AF
1
EP6FIFOBCH
E6B0
1
EP6FIFOBCL
E6B1
1
EP8FIFOBCH
E6B2
1
EP8FIFOBCL
E6B3
1
SUDPTRH
E6B4
1
SUDPTRL
E6B5
E6B8
1
2
8
SUDPTRCTL
Reserved
SET-UPDAT
E6C0
E6C1
1
1
GPIF
GPIFWFSELECT
GPIFIDLECS
E6C2
E6C3
E6C4
E6C5
1
1
1
1
E6C6
1
GPIFIDLECTL
GPIFCTLCFG
Reserved
Reserved
FLOWSTATE
FLOWSTATE
E6C7
E6C8
1
1
FLOWLOGIC
FLOWEQ0CTL
E6C9
1
FLOWEQ1CTL
E6CA
E6CB
1
1
FLOWHOLDOFF
FLOWSTB
E6CC
1
FLOWSTBEDGE
E6CD
E6CE
1
1
FLOWSTBPERIOD
GPIFTCB3[10]
E6CF
1
GPIFTCB2[10]
E6D0
1
GPIFTCB1[10]
E6D1
1
GPIFTCB0[10]
2
Reserved
Reserved
Description
Endpoint 1 IN control and
status
Endpoint 2 control and
status
b7
0
b6
0
b5
0
b4
0
b3
0
b2
0
b1
BUSY
b0
STALL
Default Access
00000000 bbbbbbrb
0
NPAK2
NPAK1
NPAK0
FULL
EMPTY
0
STALL
00101000 rrrrrrrb
Endpoint 4 control and
status
Endpoint 6 control and
status
Endpoint 8 control and
status
Endpoint 2 Slave FIFO flags
Endpoint 4 Slave FIFO flags
Endpoint 6 Slave FIFO flags
Endpoint 8 Slave FIFO flags
Endpoint 2 Slave FIFO
total byte count H
Endpoint 2 Slave FIFO
total byte count L
Endpoint 4 Slave FIFO
total byte count H
0
0
NPAK1
NPAK0
FULL
EMPTY
0
STALL
00101000 rrrrrrrb
0
NPAK2
NPAK1
NPAK0
FULL
EMPTY
0
STALL
00000100 rrrrrrrb
0
0
NPAK1
NPAK0
FULL
EMPTY
0
STALL
00000100 rrrrrrrb
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
BC12
0
0
0
0
BC11
PF
PF
PF
PF
BC10
EF
EF
EF
EF
BC9
FF
FF
FF
FF
BC8
00000010 R
00000010 R
00000110 R
00000110 R
00000000 R
BC7
BC6
BC5
BC4
BC3
BC2
BC1
BC0
00000000 R
0
0
0
0
0
BC10
BC9
BC8
00000000 R
Endpoint 4 Slave FIFO
total byte count L
Endpoint 6 Slave FIFO
total byte count H
Endpoint 6 Slave FIFO
total byte count L
Endpoint 8 Slave FIFO
total byte count H
Endpoint 8 Slave FIFO
total byte count L
Setup data pointer high
address byte
Setup data pointer low
address byte
Setup data pointer auto mode
BC7
BC6
BC5
BC4
BC3
BC2
BC1
BC0
00000000 R
8 bytes of setup data
SET-UPDAT[0] =
bmRequestType
SET-UPDAT[1] =
bmRequest
SET-UPDAT[2:3] = wValue
SET-UPDAT[4:5] = wIndex
SET-UPDAT[6:7] = wLength
Waveform selector
GPIF Done, GPIF Idle drive
mode
Inactive bus, CTL states
CTL drive type
0
0
0
0
BC11
BC10
BC9
BC8
00000000 R
BC7
BC6
BC5
BC4
BC3
BC2
BC1
BC0
00000000 R
0
0
0
0
0
BC10
BC9
BC8
00000000 R
BC7
BC6
BC5
BC4
BC3
BC2
BC1
BC0
00000000 R
A15
A14
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
0
0
0
0
0
0
0
0
D7
D6
D5
D4
D3
D2
D1
D0
FIFOWR1
0
FIFOWR0
0
FIFORD1
0
FIFORD0
IDLEDRV
11100100 RW
10000000 RW
0
0
CTL2
CTL2
CTL1
CTL1
CTL0
CTL0
11111111 RW
00000000 RW
00000000
00000000
SINGLEWR1 SINGLEWR0 SINGLERD1 SINGLERD0
DONE
0
0
0
0
TRICTL
0
0
0
0
0
0
Flowstate enable and
FSE
0
0
0
selector
Flowstate logic
LFUNC1
LFUNC0
TERMA2
TERMA1
CTL-pin states in flow state
CTL0E3
CTL0E2
CTL0E1
CTL0E0
(when Logic = 0)
CTL-pin states in flow state
CTL0E3
CTL0E2
CTL0E1
CTL0E0
(when Logic = 1)
Holdoff configuration
HOPERIOD3 HOPERIOD2 HOPERIOD1 HOPERIOD0
Flowstate strobe
SLAVE
RDYASYNC CTLTOGL
SUSTAIN
configuration
Flowstate rising/falling edge
0
0
0
0
configuration
Master strobe half period
D7
D6
D5
D4
GPIF transaction count
TC31
TC30
TC29
TC28
Byte 3
GPIF transaction count
TC23
TC22
TC21
TC20
Byte 2
GPIF transaction count
TC15
TC14
TC13
TC12
Byte 1
GPIF transaction count
TC7
TC6
TC5
TC4
Byte 0
Document # 001-06120 Rev *I
xxxxxxxx RW
xxxxxxx0 bbbbbbbr
SDPAUTO 00000001 RW
xxxxxxxx R
0
FS2
FS1
FS0
TERMA0
0
TERMB2
CTL2
TERMB1
CTL1
TERMB0
CTL0
00000000 RW
00000000 RW
00000000 brrrrbbb
0
CTL2
CTL1
CTL0
00000000 RW
HOSTATE
0
HOCTL2
MSTB2
HOCTL1
MSTB1
HOCTL0
MSTB0
00010010 RW
00100000 RW
0
0
FALLING
RISING
00000001 rrrrrrbb
D3
TC27
D2
TC26
D1
TC25
D0
TC24
00000010 RW
00000000 RW
TC19
TC18
TC17
TC16
00000000 RW
TC11
TC10
TC9
TC8
00000000 RW
TC3
TC2
TC1
TC0
00000001 RW
00000000 RW
Page 19 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex
Size Name
Description
Reserved
[10]
E6D2 1 EP2GPIFFLGSEL
Endpoint 2 GPIF flag
select
E6D3 1 EP2GPIFPFSTOP Endpoint 2 GPIF stop transaction on program flag
E6D4 1 EP2GPIFTRIG[10]
Endpoint 2 GPIF trigger
3 Reserved
Reserved
Reserved
E6DA 1 EP4GPIFFLGSEL[10] Endpoint 4 GPIF flag
select
E6DB 1 EP4GPIFPFSTOP Endpoint 4 GPIF stop transaction on GPIF flag
E6DC 1 EP4GPIFTRIG[10]
Endpoint 4 GPIF trigger
3 Reserved
Reserved
Reserved
E6E2 1 EP6GPIFFLGSEL[10] Endpoint 6 GPIF flag
select
b7
b6
b5
b4
b3
b2
b1
b0
0
0
0
0
0
0
FS1
FS0
0
0
0
0
0
0
0
x
x
x
x
x
x
x
0
0
0
0
0
0
FS1
0
0
0
0
0
0
0
x
x
x
x
x
x
x
x
0
0
0
0
0
0
FS1
FS0
E6E3
0
0
0
0
0
0
0
x
x
x
x
x
x
x
0
0
0
0
0
0
FS1
0
0
0
0
0
0
0
x
x
x
x
x
x
x
x
D15
D14
D13
D12
D11
D10
D9
D8
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx R
INTRDY
SAS
TCXRDY5
0
0
0
0
0
0
x
0
x
0
x
0
x
0
x
0
x
RDY1
x
RDY0
x
D7
D7
D7
D6
D6
D6
D5
D5
D5
D4
D4
D4
D3
D3
D3
D2
D2
D2
D1
D1
D1
D0
D0
D0
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
xxxxxxxx RW
xxxxxxxx RW
RW
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
D7
D6
D5
D4
D3
D2
D1
D0
xxxxxxxx RW
0
DISCON
0
0
0
0
0
400KHZ
xxxxxxxx n/a
E6E4
1
EP6GPIFPFSTOP
1
3
EP6GPIFTRIG[10]
E6EA
1
E6EB
1
E6EC
E6F0
1
3
1
E6F1
1
E6F2
1
E6F3
1
E6F4
E6F5
E6F6
1
1
2
E740
E780
E7C0
E800
F000
F400
F600
F800
FC00
FE00
xxxx
Endpoint 6 GPIF stop transaction on program flag
Endpoint 6 GPIF trigger
Reserved
Reserved
Reserved
EP8GPIFFLGSEL[10] Endpoint 8 GPIF flag
select
EP8GPIFPFSTOP Endpoint 8 GPIF stop transaction on program flag
EP8GPIFTRIG[10]
Endpoint 8 GPIF trigger
Reserved
XGPIFSGLDATH
GPIF Data H
(16-bit mode only)
XGPIFSGLDATLX
Read/Write GPIF Data L and
trigger transaction
XGPIFSGLDATLRead GPIF Data L, no transNOX
action trigger
GPIFREADYCFG
Internal RDY, sync/async,
RDY pin states
GPIFREADYSTAT
GPIF ready status
GPIFABORT
Abort GPIF waveforms
Reserved
ENDPOINT BUFFERS
64 EP0BUF
EP0-IN/-OUT buffer
64 EP10UTBUF
EP1-OUT buffer
64 EP1INBUF
EP1-IN buffer
2048 Reserved
1024 EP2FIFOBUF
512/1024-byte EP 2/Slave
FIFO buffer (IN or OUT)
512 EP4FIFOBUF
512 byte EP 4/Slave FIFO
buffer (IN or OUT)
512 Reserved
1024 EP6FIFOBUF
512/1024-byte EP 6/Slave
FIFO buffer (IN or OUT)
512 EP8FIFOBUF
512 byte EP 8/Slave FIFO
buffer (IN or OUT)
512 Reserved
I²C Configuration Byte
Default
Access
00000000 RW
FIFO2FLAG 00000000 RW
x
FS0
xxxxxxxx W
00000000 RW
FIFO4FLAG 00000000 RW
xxxxxxxx W
00000000 RW
FIFO6FLAG 00000000 RW
x
FS0
xxxxxxxx W
00000000 RW
FIFO8FLAG 00000000 RW
xxxxxxxx W
00000000 bbbrrrrr
00xxxxxx R
xxxxxxxx W
[12]
Note
12. If no EEPROM is detected by the SIE then the default is 00000000.
Document # 001-06120 Rev *I
Page 20 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex
80
81
Size Name
Description
Special Function Registers (SFRs)
[13]
1 IOA
Port A (bit addressable)
1 SP
Stack Pointer
b7
b6
b5
b4
b3
b2
b1
b0
Default
D7
D7
D6
D6
D5
D5
D4
D4
D3
D3
D2
D2
D1
D1
D0
D0
xxxxxxxx RW
00000111 RW
A7
A15
A7
A15
0
SMOD0
TF1
A6
A14
A6
A14
0
x
TR1
A5
A13
A5
A13
0
1
TF0
A4
A12
A4
A12
0
1
TR0
A3
A11
A3
A11
0
x
IE1
A2
A10
A2
A10
0
x
IT1
A1
A9
A1
A9
0
x
IE0
A0
A8
A0
A8
SEL
IDLE
IT0
00000000 RW
00000000 RW
00000000 RW
00000000 RW
00000000 RW
00110000 RW
00000000 RW
GATE
CT
M1
M0
GATE
CT
M1
M0
00000000 RW
D7
D7
D15
D15
x
D6
D6
D14
D14
x
D5
D5
D13
D13
T2M
D4
D4
D12
D12
T1M
D3
D3
D11
D11
T0M
D2
D2
D10
D10
MD2
D1
D1
D9
D9
MD1
D0
D0
D8
D8
MD0
00000000 RW
00000000 RW
00000000 RW
00000000 RW
00000001 RW
D7
IE5
A15
D6
IE4
A14
D5
I²CINT
A13
D4
USBNT
A12
D3
1
A11
D2
0
A10
D1
0
A9
D0
0
A8
xxxxxxxx RW
00001000 RW
00000000 RW
Serial Port 0 Control
(bit addressable)
Serial Port 0 data buffer
Autopointer 1 address H
Autopointer 1 address L
SM0_0
SM1_0
SM2_0
REN_0
TB8_0
RB8_0
TI_0
RI_0
00000000 RW
D7
A15
A7
D6
A14
A6
D5
A13
A5
D4
A12
A4
D3
A11
A3
D2
A10
A2
D1
A9
A1
D0
A8
A0
00000000 RW
00000000 RW
00000000 RW
Autopointer 2 address H
Autopointer 2 address L
A15
A7
A14
A6
A13
A5
A12
A4
A11
A3
A10
A2
A9
A1
A8
A0
00000000 RW
00000000 RW
Port C (bit addressable)
Interrupt 2 Clear
D7
x
x
D6
x
x
D5
x
x
D4
x
x
D3
x
x
D2
x
x
D1
x
x
D0
x
x
xxxxxxxx RW
xxxxxxxx W
xxxxxxxx W
Interrupt Enable
(bit addressable)
EA
ES1
ET2
ES0
ET1
EX1
ET0
EX0
00000000 RW
EP8F
0
EP8E
EP4PF
EP6F
EP4EF
EP6E
EP4FF
EP4F
0
EP4E
EP2PF
EP2F
EP2EF
EP2E
EP2FF
01011010 R
00100010 R
0
EP8PF
EP8EF
EP8FF
0
EP6PF
EP6EF
EP6FF
01100110 R
0
D7
D7
0
D6
D6
0
D5
D5
0
D4
D4
0
D3
D3
APTR2INC
D2
D2
APTR1INC
D1
D1
APTREN
D0
D0
00000110 RW
xxxxxxxx RW
xxxxxxxx RW
D7
D7
D7
D7
D7
D6
D6
D6
D6
D6
D5
D5
D5
D5
D5
D4
D4
D4
D4
D4
D3
D3
D3
D3
D3
D2
D2
D2
D2
D2
D1
D1
D1
D1
D1
D0
D0
D0
D0
D0
00000000 RW
00000000 RW
00000000 RW
00000000 RW
00000000 RW
1
PS1
PT2
PS0
PT1
PX1
PT0
PX0
10000000 RW
0
DONE
0
0
0
0
0
0
0
0
D15
D14
D13
D12
D11
D10
D9
D8
xxxxxxxx RW
D7
D7
D6
D6
D5
D5
D4
D4
D3
D3
D2
D2
D1
D1
D0
D0
xxxxxxxx RW
xxxxxxxx R
82
83
84
85
86
87
88
1
1
1
1
1
1
1
DPL0
DPH0
DPL1[13]
DPH1[13]
DPS[13]
PCON
TCON
89
1
TMOD
8A
8B
8C
8D
8E
1
1
1
1
1
TL0
TL1
TH0
TH1
CKCON[13]
8F
90
91
92
1
1
1
1
Reserved
IOB[13]
EXIF[13]
MPAGE[13]
93
98
5
1
Reserved
SCON0
99
9A
9B
9C
9D
9E
9F
A0
A1
A2
A3
A8
1
1
1
1
1
1
1
1
1
1
5
1
SBUF0
AUTOPTRH1[13]
AUTOPTRL1[13]
Reserved
AUTOPTRH2[13]
AUTOPTRL2[13]
Reserved
IOC[13]
INT2CLR[13]
Reserved
Reserved
IE
A9
AA
AB
1
1
1
Reserved
EP2468STAT[13]
EP24FIFOFLGS
AC
1
EP68FIFOFLGS
AD
AF
B0
B1
2
1
1
1
B2
B3
B4
B5
B6
B7
B8
1
1
1
1
1
1
1
B9
BA
BB
1
1
1
BC
BD
1
1
BE
BF
1
1
Reserved
AUTOPTRSETUP[13] Autopointer 1 and 2 Setup
IOD[13]
Port D (bit addressable)
IOE[13]
Port E
(NOT bit addressable)
OEA[13]
Port A Output Enable
OEB[13]
Port B Output Enable
OEC[13]
Port C Output Enable
OED[13]
Port D Output Enable
OEE[13]
Port E Output Enable
Reserved
IP
Interrupt Priority (bit addressable)
Reserved
EP01STAT[13]
Endpoint 0 and 1 Status
GPIFTRIG[13, 10]
Endpoint 2,4,6,8 GPIF Slave
FIFO trigger
Reserved
GPIFSGLDATH[13] GPIF Data H (16-bit mode
only)
GPIFSGLDATLX[13] GPIF Data L w/trigger
GPIFSGLDATLGPIF Data L w/no trigger
NOX[13]
[13]
[13]
Data Pointer 0 L
Data Pointer 0 H
Data Pointer 1 L
Data Pointer 1 H
Data Pointer 0/1 select
Power control
Timer/Counter control
(bit addressable)
Timer/Counter mode
control
Timer 0 reload L
Timer 1 reload L
Timer 0 reload H
Timer 1 reload H
Clock control
Port B (bit addressable)
External interrupt flags
Upper address byte of MOVX
using @R0/@R1
Endpoint 2,4,6,8 status flags
Endpoint 2,4 Slave FIFO
status flags
Endpoint 6,8 Slave FIFO
status flags
EP1INBSY EP1OUTBSY
RW
EP1
EP0BSY
EP0
Access
00000000 R
10000xxx brrrrbbb
Note
13. SFRs not part of the standard 8051 architecture.
Document # 001-06120 Rev *I
Page 21 of 40
[+] Feedback
CY7C68053
Table 8. FX2LP18 Register Summary (continued)
Hex
C0
Size Name
1 SCON1[13]
Description
Serial Port 1 Control (bit
addressable)
Serial Port 1 Data Buffer
b7
SM0_1
b6
SM1_1
b5
SM2_1
b4
REN_1
b3
TB8_1
b2
RB8_1
b1
TI_1
b0
RI_1
Default Access
00000000 RW
D7
D6
D5
D4
D3
D2
D1
D0
00000000 RW
Timer/Counter 2 Control (bit
addressable)
TF2
EXF2
RCLK
TCLK
EXEN2
TR2
CT2
CPRL2
00000000 RW
Capture for Timer 2,
auto-reload, up counter
Capture for Timer 2,
auto-reload, up counter
Timer 2 Reload L
Timer 2 Reload H
D7
D6
D5
D4
D3
D2
D1
D0
00000000 RW
D7
D6
D5
D4
D3
D2
D1
D0
00000000 RW
D7
D15
D6
D14
D5
D13
D4
D12
D3
D11
D2
D10
D1
D9
D0
D8
00000000 RW
00000000 RW
CY
AC
F0
RS1
RS0
OV
F1
P
00000000 RW
C1
C2
1
6
SBUF1[13]
Reserved
C8
1
T2CON
C9
CA
1
1
Reserved
RCAP2L
CB
1
RCAP2H
CC
CD
CE
D0
1
1
2
1
TL2
TH2
Reserved
PSW
D1
D8
D9
7
1
7
Reserved
EICON[13]
Reserved
External Interrupt Control
SMOD1
1
ERESI
RESI
INT6
0
0
0
01000000 RW
E0
1
ACC
Accumulator (bit addressable)
D7
D6
D5
D4
D3
D2
D1
D0
00000000 RW
E1
E8
E9
F0
F1
F8
7
1
7
1
7
1
Reserved
EIE[13]
Reserved
B
Reserved
EIP[13]
External Interrupt Enables
1
1
1
EX6
EX5
EX4
EI²C
EUSB
11100000 RW
D7
D6
D5
D4
D3
D2
D1
D0
00000000 RW
1
1
1
PX6
PX5
PX4
PI²C
PUSB
11100000 RW
F9
7
Reserved
Program Status Word (bit addressable)
B (bit addressable)
External Interrupt Priority
control
Ledgend
R = All bits read only
W = All bits write only
r = Read-only bit
w = Write-only bit
b = Both read/write bit
Document # 001-06120 Rev *I
Page 22 of 40
[+] Feedback
CY7C68053
6. Absolute Maximum Ratings
Storage Temperature ............................................................. ..................................................................................... –65°C to +150°C
Ambient Temperature with Power Supplied
Industrial ................................................................................ ....................................................................................... –40°C to +85°C
Supply Voltage to Ground Potential
For 3.3V Power domain......................................................... ........................................................................................ –0.5V to +4.0V
For 1.8V Power domain......................................................... ........................................................................................ –0.5V to +2.0V
DC Input Voltage to Any Input Pin
For pins under 3.3V Power Domain ...................................... ....................................................................................................3.6V[14]
For pins under 1.8V - 3.3V Power Domain (GPIOs).............. ..................................................................................... 1.89V to 3.6V[14]
(The GPIOs are not over voltage tolerant, except the SCL and SDA pins, which are 3.3V tolerant)
DC Voltage Applied to Outputs in High Z State ..................... ............................................................................... –0.5V to VCC +0.5V
Maximum Power Dissipation
From AVcc Supply ................................................................. .....................................................................................................90 mW
From I/O Supply .................................................................... .....................................................................................................36 mW
From Core Supply ................................................................. .....................................................................................................95 mW
Static Discharge Voltage........................................................ ....................................................................................................>2000V
(I2C SCL and SDA pins only ................................................. .............................................................................................. ... >1500V)
Maximum Output Current, per I/O port .................................. ......................................................................................................10 mA
7. Operating Conditions
TA (Ambient Temperature Under Bias)
Industrial ................................................................................ ....................................................................................... –40°C to +85°C
Supply Voltage
3.3V Power Supply ................................................................ ............................................................................................ 3.0V to 3.6V
1.8V Power Supply ................................................................ ......................................................................................... 1.71V to1.89V
Ground Voltage...................................................................... ............................................................................................................ 0V
FOSC (Oscillator or Crystal Frequency).................................. .................................................................................. 24 MHz ± 100 ppm
............................................................................................... .................................................................................... Parallel Resonant
............................................................................................... ...................................................................................500 μW drive level
............................................................................................... .............................................................................Load capacitors 12 pF
Note
14. Do not power I/O when chip power is OFF.
Document # 001-06120 Rev *I
Page 23 of 40
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CY7C68053
8. DC Characteristics
Table 9. DC Characteristics
Parameter
Description
Conditions
Min
Typ
Max
Unit
AVCC
3.3V supply (to oscillator and PHY)
3.00
3.3
3.60
V
VCC_IO
1.8V to 3.3V supply (to I/O)
1.71
1.8
3.60
V
VCC_A
1.8V supply to analog core
1.71
1.8
1.89
V
VCC_D
1.8V supply to digital core
1.71
1.8
1.89
V
VIH
Input HIGH voltage
0.6*VCC_IO
VCC_IO+10%
V
VIL
Input LOW voltage
0
0.3*VCC_IO
V
VIH_X
Crystal input HIGH voltage
2.0
3.60
V
VIL_X
Crystal input LOW voltage
–0.5
0.8
V
Hysteresis
50
II
Input leakage current
VOH
Output voltage HIGH
IOUT = 4 mA
VOL
Output LOW voltage
IOUT = –4 mA
mV
0< VIN < VCC_IO
±10
μA
0.4
V
VCC_IO – 0.4
V
IOH
Output current HIGH
4
mA
IOL
Output current LOW
4
mA
CIN
Input pin capacitance
Except D+/D–
10
pF
D+/D–
15
pF
μA
μA
ISUSP
ICC_AVcc
ICC_IO
ICC_CORE
TRESET
Suspend current
Supply current (AVCC)
Supply current (VCC_IO)
Supply current (VCC_CORE)
Reset time after valid power
Pin reset after powered on
Connected
220
380[15]
Disconnected
20
150[15]
8051 running, connected to USB HS
15
25
mA
8051 running, connected to USB FS
10
20
mA
8051 running, connected to USB HS
3
10
mA
8051 running, connected to USB FS
1
5
mA
8051 running, connected to USB HS
32
50
mA
8051 running, connected to USB FS
24
40
mA
VCC min = 3.0V
5.0
ms
200
μs
Note
15. Measured at maximum VCC, 25°C.
Document # 001-06120 Rev *I
Page 24 of 40
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CY7C68053
9. AC Electrical Characteristics
9.1 USB Transceiver
USB 2.0-compliant in full and high speed modes.
9.2 GPIF Synchronous Signals
Figure 8. GPIF Synchronous Signals Timing Diagram[16]
tIFCLK
IFCLK
tSGA
GPIFADR[8:0]
RDYX
tSRY
tRYH
DATA(input)
valid
tSGD
tDAH
CTLX
tXCTL
DATA(output)
N
N+1
tXGD
Table 10.GPIF Synchronous Signals Parameters with Internally Sourced IFCLK[16,17]
Parameter
Description
tIFCLK
IFCLK period
tSRY
RDYX to clock setup time
Min
Max
Unit
20.83
ns
8.9
ns
0
ns
9.2
ns
tRYH
Clock to RDYX
tSGD
GPIF data to clock setup time
tDAH
GPIF data hold time
tXGD
Clock to GPIF data output propagation delay
11
ns
tXCTL
Clock to CTLX output propagation delay
6.7
ns
Min
Max
Unit
20.83
200
0
ns
8
Table 11.GPIF Synchronous Signals Parameters with Externally Sourced IFCLK[17]
Parameter
Description
period[18]
tIFCLK
IFCLK
tSRY
RDYX to clock setup time
2.9
ns
ns
tRYH
Clock to RDYX
3.7
ns
tSGD
GPIF data to clock setup time
3.2
ns
tDAH
GPIF data hold time
4.5
tXGD
Clock to GPIF data output propagation delay
tXCTL
Clock to CTLX output propagation delay
ns
15
ns
13.06
ns
Notes
16. Dashed lines denote signals with programmable polarity.
17. GPIF asynchronous RDYx signals have a minimum setup time of 50 ns when using internal 48 MHz IFCLK.
18. IFCLK must not exceed 48 MHz.
Document # 001-06120 Rev *I
Page 25 of 40
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CY7C68053
9.3 Slave FIFO Synchronous Read
Figure 9. Slave FIFO Synchronous Read Timing Diagram[16]
tIFCLK
IFCLK
tSRD
tRDH
SLRD
tXFLG
FLAGS
DATA
N
tOEon
N+1
tXFD
tOEoff
SLOE
Table 12.Slave FIFO Synchronous Read Parameters with Internally Sourced IFCLK[17]
Parameter
Description
Min
Max
Unit
tIFCLK
IFCLK period
20.83
ns
tSRD
SLRD to clock setup time
18.7
ns
tRDH
Clock to SLRD hold time
0
tOEon
SLOE turn-on to FIFO data valid
tOEoff
SLOE turn-off to FIFO data hold
10.5
ns
tXFLG
Clock to FLAGS output propagation delay
9.5
ns
tXFD
Clock to FIFO data output propagation delay
11
ns
ns
10.5
2.15
ns
Table 13.Slave FIFO Synchronous Read Parameters with Externally Sourced IFCLK[17]
Parameter
Min
Max
Unit
tIFCLK
IFCLK period
Description
20.83
200
ns
tSRD
SLRD to clock setup time
12.7
ns
tRDH
Clock to SLRD hold time
3.7
ns
tOEon
SLOE turn-on to FIFO data valid
tOEoff
SLOE turn-off to FIFO data hold
tXFLG
tXFD
10.5
ns
10.5
ns
Clock to FLAGS output propagation delay
13.5
ns
Clock to FIFO data output propagation delay
17.31
ns
Document # 001-06120 Rev *I
2.15
Page 26 of 40
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CY7C68053
9.4 Slave FIFO Asynchronous Read
Figure 10. Slave FIFO Asynchronous Read Timing Diagram[16]
tRDpwh
SLRD
tRDpwl
FLAGS
tXFD
tXFLG
DATA
N
tOEon
N+1
tOEoff
SLOE
Table 14.Slave FIFO Asynchronous Read Parameters[19]
Parameter
Description
Min
tRDpwl
SLRD pulse width LOW
50
tRDpwh
SLRD pulse width HIGH
50
tXFLG
SLRD to FLAGS output propagation delay
tXFD
SLRD to FIFO data output propagation delay
tOEon
SLOE turn-on to FIFO data valid
tOEoff
SLOE turn-off to FIFO data hold
2.15
Max
Unit
ns
ns
70
ns
15
ns
10.5
ns
10.5
ns
Note
19. Slave FIFO asynchronous parameter values use internal IFCLK setting at 48 MHz.
Document # 001-06120 Rev *I
Page 27 of 40
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9.5 Slave FIFO Synchronous Write
Figure 11. Slave FIFO Synchronous Write Timing Diagram[16]
tIFCLK
IFCLK
SLWR
DATA
tSWR
tWRH
N
Z
tSFD
Z
tFDH
FLAGS
tXFLG
Table 15.Slave FIFO Synchronous Write Parameters with Internally Sourced IFCLK[17]
Parameter
Description
Min
Max
Unit
tIFCLK
IFCLK period
20.83
ns
tSWR
SLWR to clock setup time
18.1
ns
tWRH
Clock to SLWR hold time
0
ns
tSFD
FIFO data to clock setup time
10.64
ns
tFDH
Clock to FIFO data hold time
0
tXFLG
Clock to FLAGS output propagation time
ns
9.5
ns
Table 16.Slave FIFO Synchronous Write Parameters with Externally Sourced IFCLK[10]
Min
Max
Unit
tIFCLK
Parameter
IFCLK period
Description
20.83
200
ns
tSWR
SLWR to clock setup time
12.1
ns
tWRH
Clock to SLWR hold time
3.6
ns
tSFD
FIFO data to clock setup time
3.2
ns
tFDH
Clock to FIFO data hold time
4.5
ns
tXFLG
Clock to FLAGS output propagation time
Document # 001-06120 Rev *I
13.5
ns
Page 28 of 40
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CY7C68053
9.6 Slave FIFO Asynchronous Write
Figure 12. Slave FIFO Asynchronous Write Timing Diagram[16]
tWRpwh
SLWR
tWRpwl
tSFD
tFDH
DATA
tXFD
FLAGS
Table 17.Slave FIFO Asynchronous Write Parameters with Internally Sourced IFCLK[19]
Parameter
Description
Min
Max
50
Unit
tWRpwl
SLWR pulse LOW
ns
tWRpwh
SLWR pulse HIGH
50
ns
tSFD
SLWR to FIFO data setup time
10
ns
tFDH
FIFO data to SLWR hold time
10
tXFD
SLWR to FLAGS output propagation delay
ns
70
ns
9.7 Slave FIFO Synchronous Packet End Strobe
Figure 13. Slave FIFO Synchronous Packet End Strobe Timing Diagram[16]
IFCLK
tPEH
PKTEND
tSPE
FLAGS
tXFLG
Table 18.Slave FIFO Synchronous Packet End Strobe Parameters with Internally Sourced IFCLK[10]
Parameter
Description
Min
Max
Unit
tIFCLK
IFCLK period
20.83
tSPE
PKTEND to clock setup time
14.6
ns
tPEH
Clock to PKTEND hold time
0
ns
tXFLG
Clock to FLAGS output propagation delay
ns
9.5
ns
Table 19.Slave FIFO Synchronous Packet End Strobe Parameters with Externally Sourced IFCLK[10]
Parameter
Description
Min
Max
Unit
20.83
200
ns
tIFCLK
IFCLK period
tSPE
PKTEND to clock setup time
8.6
ns
tPEH
Clock to PKTEND hold time
3.04
ns
tXFLG
Clock to FLAGS output propagation delay
Document # 001-06120 Rev *I
13.5
ns
Page 29 of 40
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CY7C68053
There is no specific timing requirement to be met for asserting
the PKTEND pin with regards to asserting SLWR. PKTEND can
be asserted with the last data value clocked into the FIFOs or
thereafter. The only consideration is that the setup time tSPE and
the hold time tPEH must be met.
least one clock cycle after the rising edge that caused the last
byte/word to be clocked into the previous auto committed packet.
Figure 14 shows this scenario. X is the value the AUTOINLEN
register is set to when the IN endpoint is configured to be in auto
mode.
Although there are no specific timing requirements for the
PKTEND assertion, there is a specific corner case condition that
needs attention while using the PKTEND to commit a one
byte/word packet. There is an additional timing requirement to be
met when the FIFO is configured to operate in auto mode and
you want to send two packets back to back: a full packet (full
defined as the number of bytes in the FIFO meeting the level set
in AUTOINLEN register) committed automatically followed by a
short one byte/word packet committed manually using the
PKTEND pin. In this scenario, make sure to assert PKTEND at
Figure 14 shows a scenario where two packets are committed.
The first packet is committed automatically when the number of
bytes in the FIFO reaches X (value set in AUTOINLEN register)
and the second one byte/word short packet is committed
manually using PKTEND. Note that there is at least one IFCLK
cycle timing between the assertion of PKTEND and clocking of
the last byte of the previous packet (causing the packet to be
committed automatically). Failing to adhere to this timing, results
in the FX2LP18 failing to send the one byte/word short packet.
Figure 14. Slave FIFO Synchronous Write Sequence and Timing Diagram[16]
tIFCLK
IFCLK
tSFA
tFAH
FIFOADR
>= tWRH
>= tSWR
SLWR
tFDH
tSFD
tSFD
X-4
DATA
tFDH
X-3
tFDH
tSFD
tFDH
tSFD
X-2
tSFD
X-1
X
tFDH
tSFD
tFDH
1
At least one IFCLK cycle
tSPE
tPEH
PKTEND
9.8 Slave FIFO Asynchronous Packet End Strobe
Figure 15. Slave FIFO Asynchronous Packet End Strobe Timing Diagram[16]
tPEpwh
PKTEND
tPEpwl
FLAGS
tXFLG
Table 20.Slave FIFO Asynchronous Packet End Strobe Parameters[19]
Parameter
Description
Min
Max
Unit
tPEpwl
PKTEND pulse width LOW
50
ns
tPWpwh
PKTEND pulse width HIGH
50
ns
tXFLG
PKTEND to FLAGS output propagation delay
Document # 001-06120 Rev *I
115
ns
Page 30 of 40
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9.9 Slave FIFO Output Enable
Figure 16. Slave FIFO Output Enable Timing Diagram[16]
SLOE
tOEon
DATA
tOEoff
Table 21.Slave FIFO Output Enable Parameters
Parameter
Description
tOEon
SLOE assert to FIFO data output
tOEoff
SLOE deassert to FIFO data hold
Min
Max
Unit
10.5
ns
2.15
10.5
ns
9.10 Slave FIFO Address to Flags/Data
Figure 17. Slave FIFO Address to Flags/Data Timing Diagram[16]
FIFOADR [1.0]
tXFLG
FLAGS
tXFD
DATA
N
N+1
Table 22.Slave FIFO Address to Flags/Data Parameters
Max
Unit
tXFLG
Parameter
FIFOADR[1:0] to flags output propagation delay
Description
10.7
ns
tXFD
FIFOADR[1:0] to FIFO data output propagation delay
14.3
ns
Document # 001-06120 Rev *I
Min
Page 31 of 40
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9.11 Slave FIFO Synchronous Address
Figure 18. Slave FIFO Synchronous Address Timing Diagram[16]
IFCLK
SLCS/FIFOADR [1:0]
tSFA
tFAH
Table 23.Slave FIFO Synchronous Address Parameters[10]
Parameter
Description
Min
Max
Unit
20.83
200
ns
tIFCLK
Interface clock period
tSFA
FIFOADR[1:0] to clock setup time
25
ns
tFAH
Clock to FIFOADR[1:0] hold time
10
ns
9.12 Slave FIFO Asynchronous Address
Figure 19. Slave FIFO Asynchronous Address Timing Diagram[16]
SLCS/FIFOADR [1:0]
tSFA
tFAH
SLRD/SLWR/PKTEND
Slave FIFO Asynchronous Address Parameters[19]
Parameter
Description
Min
Max
Unit
tSFA
FIFOADR[1:0] to SLRD/SLWR/PKTEND setup time
10
ns
tFAH
RD/WR/PKTEND to FIFOADR[1:0] hold time
10
ns
Document # 001-06120 Rev *I
Page 32 of 40
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9.13 Sequence Diagram
Various sequence diagrams and examples are presented in this section.
9.13.1 Single and Burst Synchronous Read Example
Figure 20. Slave FIFO Synchronous Read Sequence and Timing Diagram[16]
tIFCLK
IFCLK
tSFA
tSFA
tFAH
tFAH
FIFOADR
t=0
tSRD
T=0
tRDH
>= tSRD
>= tRDH
SLRD
t=3
t=2
T=3
T=2
SLCS
tXFLG
FLAGS
tXFD
tXFD
Data Driven: N
DATA
N+1
N+1
N+2
N+3
tOEon
tOEoff
tOEon
tXFD
tXFD
N+4
tOEoff
SLOE
t=4
t=1
T=4
T=1
Figure 21. Slave FIFO Synchronous Sequence of Events Diagram
IFCLK
FIFO POINTER
N
IFCLK
IFCLK
N
N+1
FIFO DATA BUS Not Driven
Driven: N
N+1
Not Driven
■
At t = 0 the FIFO address is stable and the signal SLCS is
asserted (SLCS may be tied low in some applications).
Note tSFA has a minimum of 25 ns. This means that when
IFCLK is running at 48 MHz, the FIFO address setup time is
more than one IFCLK cycle.
■
At t = 1, SLOE is asserted. SLOE is an output enable only
whose sole function is to drive the data bus. The data that is
driven on the bus is the data that the internal FIFO pointer is
currently pointing to. In this example, it is the first data value in
the FIFO.
Note The data is prefetched and driven on the bus when SLOE
is asserted.
At t = 2, SLRD is asserted. SLRD must meet the setup time of
tSRD (time from asserting the SLRD signal to the rising edge of
the IFCLK) and maintain a minimum hold time of tRDH (time
from the IFCLK edge to the deassertion of the SLRD signal).
Document # 001-06120 Rev *I
N+1
SLOE
Figure 20 shows the timing relationship of the SLAVE FIFO
signals during a synchronous FIFO read using IFCLK as the
synchronizing clock. The diagram illustrates a single read
followed by a burst read.
■
IFCLK
N+1
SLOE
SLRD
SLRD
SLOE
IFCLK
IFCLK
N+2
IFCLK
N+3
IFCLK
N+4
SLRD
N+1
IFCLK
N+4
SLRD
N+2
N+3
N+4
IFCLK
N+4
SLOE
N+4
Not Driven
If the SLCS signal is used, it must be asserted before SLRD
(that is, the SLCS and SLRD signals must both be asserted to
start a valid read condition).
■
The FIFO pointer is updated on the rising edge of the IFCLK
while SLRD is asserted. This starts the propagation of data
from the newly addressed location to the data bus. After a
propagation delay of tXFD (measured from the rising edge of
IFCLK) the new data value is present. N is the first data value
read from the FIFO. To have data on the FIFO data bus, SLOE
must also be asserted.
The same sequence of events is shown for a burst read and is
marked with the time indicators of T = 0 through 5.
Note For the burst mode, the SLRD and SLOE are left asserted
during the entire duration of the read. In the burst read mode,
when SLOE is asserted, data indexed by the FIFO pointer is on
the data bus. During the first read cycle on the rising edge of the
clock, the FIFO pointer is updated and increments to point to
address N+1. For each subsequent rising edge of IFCLK while
the SLRD is asserted, the FIFO pointer is incremented and the
next data value is placed on the data bus.
Page 33 of 40
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CY7C68053
9.13.2 Single and Burst Synchronous Write
Figure 22. Slave FIFO Synchronous Write Sequence and Timing Diagram[16]
tIFCLK
IFCLK
tSFA
tSFA
tFAH
tFAH
FIFOADR
t=0
tSWR
tWRH
>= tWRH
>= tSWR
T=0
SLWR
t=2
T=2
t=3
T=5
SLCS
tXFLG
tXFLG
FLAGS
tFDH
tSFD
tSFD
N+1
N
DATA
t=1
tFDH
T=1
tSFD
tSFD
tFDH
N+3
N+2
T=3
tFDH
T=4
tSPE
tPEH
PKTEND
Figure 22 shows the timing relationship of the SLAVE FIFO
signals during a synchronous write using IFCLK as the
synchronizing clock. The diagram illustrates a single write
followed by burst write of 3 bytes and committing all 4 bytes as
a short packet using the PKTEND pin.
FIFO data bus is written to the FIFO on every rising edge of
IFCLK. The FIFO pointer is updated on each rising edge of
IFCLK. In Figure 22, when the four bytes are written to the FIFO,
SLWR is deasserted. The short 4-byte packet can be committed
to the host by asserting the PKTEND signal.
■
At t = 0 the FIFO address is stable and the signal SLCS is
asserted. (SLCS may be tied low in some applications)
Note tSFA has a minimum of 25 ns. This means that when
IFCLK is running at 48 MHz, the FIFO address setup time is
more than one IFCLK cycle.
■
At t = 1, the external master/peripheral must output the data
value onto the data bus with a minimum setup time of tSFD
before the rising edge of IFCLK.
■
At t = 2, SLWR is asserted. The SLWR must meet the setup
time of tSWR (time from asserting the SLWR signal to the rising
edge of IFCLK) and maintain a minimum hold time of tWRH (time
from the IFCLK edge to the deassertion of the SLWR signal).
If the SLCS signal is used, it must be asserted before SLWR
is asserted. (That is, the SLCS and SLWR signals must both
be asserted to start a valid write condition).
There is no specific timing requirement that needs to be met for
asserting the PKTEND signal with regards to asserting the
SLWR signal. PKTEND can be asserted with the last data value
or thereafter. The only requirement is that the setup time tSPE
and the hold time tPEH must be met. In the scenario of Figure 22,
the number of data values committed includes the last value
written to the FIFO. In this example, both the data value and the
PKTEND signal are clocked on the same rising edge of IFCLK.
PKTEND can also be asserted in subsequent clock cycles. The
FIFOADDR lines must be held constant during the PKTEND
assertion.
■
While the SLWR is asserted, data is written to the FIFO and on
the rising edge of the IFCLK, the FIFO pointer is incremented.
The FIFO flag is also updated after a delay of tXFLG from the
rising edge of the clock.
The same sequence of events is also shown for a burst write and
is marked with the time indicators of T = 0 through 5.
Note For the burst mode, SLWR and SLCS are left asserted for
the entire duration of writing all the required data values. In this
burst write mode, when the SLWR is asserted, the data on the
Document # 001-06120 Rev *I
Although there are no specific timing requirements for the
PKTEND assertion, there is a specific corner case condition that
needs attention while using the PKTEND to commit a one
byte/word packet. Additional timing requirements exist when the
FIFO is configured to operate in auto mode and you want to send
two packets: a full packet (full defined as the number of bytes in
the FIFO meeting the level set in AUTOINLEN register)
committed automatically followed by a short one byte/word
packet committed manually using the PKTEND pin. In this case,
the external master must make sure to assert the PKTEND pin
at least one clock cycle after the rising edge that caused the last
byte/word to be clocked into the previous auto committed packet
(the packet with the number of bytes equal to what is set in the
AUTOINLEN register). Refer to Figure 14 on page 30 for further
details about this timing.
Page 34 of 40
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CY7C68053
9.13.3 Sequence Diagram of a Single and Burst Asynchronous Read
Figure 23. Slave FIFO Asynchronous Read Sequence and Timing Diagram[16]
tSFA
tFAH
tSFA
tFAH
FIFOADR
t=0
tRDpwl
tRDpwh
tRDpwl
T=0
tRDpwl
tRDpwh
tRDpwl
tRDpwh
tRDpwh
SLRD
t=2
t=3
T=2
T=3
T=5
T=4
T=6
SLCS
tXFLG
tXFLG
FLAGS
tXFD
Data (X)
Driven
DATA
tXFD
tXFD
N
N
N+1
N+3
N+2
tOEon
tOEoff
tOEon
tXFD
tOEoff
SLOE
t=4
t=1
T=1
T=7
Figure 24. Slave FIFO Asynchronous Read Sequence of Events Diagram
SLOE
FIFO POINTER
N
FIFO DATA BUS Not Driven
SLRD
SLRD
SLOE
SLOE
SLRD
SLRD
SLOE
N+1
N+1
N+1
N+1
N+2
N+2
N+3
N+3
Driven: X
N
N
Not Driven
N
N+1
N+1
N+2
N+2
Not Driven
■
At t = 0, the FIFO address is stable and the SLCS signal is
asserted.
■
At t = 1, SLOE is asserted. This results in the data bus being
driven. The data that is driven on to the bus is previous data;
it is data that was in the FIFO from a prior read cycle.
At t = 2, SLRD is asserted. The SLRD must meet the minimum
active pulse of tRDpwl and minimum inactive pulse width of
tRDpwh. If SLCS is used then, SLCS must be asserted before
SLRD is asserted (that is, the SLCS and SLRD signals must
both be asserted to start a valid read condition).
Document # 001-06120 Rev *I
SLRD
N
Figure 23 illustrates the timing relationship of the SLAVE FIFO
signals during an asynchronous FIFO read. It shows a single
read followed by a burst read.
■
SLRD
N
■
The data that is driven, after asserting SLRD, is the updated
data from the FIFO. This data is valid after a propagation delay
of tXFD from the activating edge of SLRD. In Figure 23, data N
is the first valid data read from the FIFO. For data to appear on
the data bus during the read cycle (for example, SLRD is
asserted), SLOE MUST be in an asserted state. SLRD and
SLOE can also be tied together.
The same sequence of events is also shown for a burst read
marked with T = 0 through 5.
Note In burst read mode, during SLOE assertion, the data bus
is in a driven state and outputs the previous data. Once SLRD is
asserted, the data from the FIFO is driven on the data bus (SLOE
must also be asserted) and then the FIFO pointer is
incremented.
Page 35 of 40
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CY7C68053
9.13.4 Sequence Diagram of a Single and Burst Asynchronous Write
Figure 25. Slave FIFO Asynchronous Write Sequence and Timing Diagram[16]
tSFA
tFAH
tSFA
tFAH
FIFOADR
t=0
tWRpwl
tWRpwh
T=0
tWRpwl
tWRpwl
tWRpwh
tWRpwl
tWRpwh
tWRpwh
SLWR
t=3
t =1
T=1
T=3
T=4
T=6
T=7
T=9
SLCS
tXFLG
tXFLG
FLAGS
tSFD tFDH
tSFD tFDH
tSFD tFDH
tSFD tFDH
N+1
N+2
N+3
N
DATA
t=2
T=2
T=5
T=8
tPEpwl
tPEpwh
PKTEND
Figure 25 illustrates the timing relationship of the SLAVE FIFO
write in an asynchronous mode. The diagram shows a single
write followed by a burst write of 3 bytes and committing the
4-byte-short packet using PKTEND.
■
At t = 0 the FIFO address is applied, ensuring that it meets the
setup time of tSFA. If SLCS is used, it must also be asserted
(SLCS may be tied low in some applications).
■
At t = 1 SLWR is asserted. SLWR must meet the minimum
active pulse of tWRpwl and minimum inactive pulse width of
tWRpwh. If the SLCS is used, it must be asserted before SLWR
is asserted.
■
At t = 2, data must be present on the bus tSFD before the
deasserting edge of SLWR.
■
At t = 3, deasserting SLWR causes the data to be written from
the data bus to the FIFO and then the FIFO pointer is
incremented. The FIFO flag is also updated after tXFLG from
the deasserting edge of SLWR.
Document # 001-06120 Rev *I
The same sequence of events is shown for a burst write and is
indicated by the timing marks of T = 0 through 5.
Note In the burst write mode, once SLWR is deasserted, the data
is written to the FIFO and then the FIFO pointer is incremented
to the next byte in the FIFO. The FIFO pointer is post
incremented.
In Figure 25 when the four bytes are written to the FIFO and
SLWR is deasserted, the short 4-byte packet can be committed
to the host using the PKTEND. The external device must be
designed to not assert SLWR and the PKTEND signal at the
same time. It must be designed to assert the PKTEND after
SLWR is deasserted and meet the minimum deasserted pulse
width. The FIFOADDR lines are to be held constant during the
PKTEND assertion.
Page 36 of 40
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CY7C68053
10. Ordering Information
Table 24. Ordering Information
Ordering Code
Package Type
CY7C68053-56BAXI
RAM Size
# Prog I/Os
8051 Address/Data
Buses
16K
24
–
56 VFBGA– Pb-free
Development Tool Kit
CY3687
MoBL-USB FX2LP18 Development Kit
11. Package Diagram
The FX2LP18 is available in a 56-pin VFBGA package.
Figure 26. 56 VFBGA (5 x 5 x 1.0 mm) 0.50 Pitch, 0.30 Ball BZ56
TOP VIEW
BOTTOM VIEW
Ø0.05 M C
Ø0.15 M C A B
PIN A1 CORNER
A1 CORNER
Ø0.30±0.05(56X)
8 7 6 5 4 3 2 1
A
B
C
D
E
F
G
H
0.50
3.50
A
B
C
D
E
F
G
H
5.00±0.10
5.00±0.10
1 2 3 4 5 6 6 8
0.50
-B3.50
-A-
5.00±0.10
5.00±0.10
0.080 C
0.45
SIDE VIEW
0.10 C
0.10(4X)
REFERENCE JEDEC: MO-195C
Document # 001-06120 Rev *I
0.160 ~0.260
1.0 max
SEATING PLANE
0.21
-C-
PACKAGE WEIGHT: 0.02 grams
001-03901-*B
Page 37 of 40
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CY7C68053
12. PCB Layout Recommendations
The following recommendations must be followed to ensure
reliable high performance operation.
■
Bypass or flyback caps on VBus, near connector, are
recommended.
■
At least a four-layer impedance controlled board is required to
maintain signal quality.
■
DPLUS and DMINUS trace lengths must be kept within 2 mm
of each other in length, with preferred length of 20 to 30 mm.
■
Specify impedance targets (ask your board vendor what they
can achieve).
■
Maintain a solid ground plane under the DPLUS and DMINUS
traces. Do not allow the plane to be split under these traces.
■
To control impedance, maintain trace widths and trace spacing
to within specifications.
■
It is preferable to have no vias placed on the DPLUS or
DMINUS trace routing.
■
Minimize stubs to minimize reflected signals.
■
■
Connections between the USB connector shell and signal
ground must be done near the USB connector.
Isolate the DPLUS and DMINUS traces from all other signal
traces by no less than 10 mm.
Document # 001-06120 Rev *I
Page 38 of 40
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CY7C68053
Document History Page
Document Title: CY7C68053 MoBL-USB FX2LP18 USB Microcontroller
Document Number: 001-06120
Rev.
ECN No.
Submission
Date
Orig. of
Change
Description of Change
**
430449
03/03/06
OSG
New data sheet
*A
434754
03/24/06
OSG
In Section 3.3, stated that SCL and SDA pins can be connected to VCC or VCC_IO
Chnged sections 3.5, 3.18.1 and pin descriptions of SCL, SDA to indicate that since
DISCON=1 after reset, an EEPROM or EEPROM emulation is required on the I2C
interface
In pin description table, renamed pin 2H (Reserved) to Ground
In Section 6, added statement “The GPIO’s are not over voltage tolerant, except the
SCL and SDA pins, which are 3.3V tolerant“
In Section 8,added a footnote to the DC char table stating that AVcc can be floated
in low power mode
In Section 8, changed VIHmax in DC char table from 3.6V to VCC_IO + 10%
*B
465471
See ECN
OSG
Changed the recommendation for the pull up resistors on I2C
Split Icc into 4 different values, corresponding to the different voltage supplies
Changed Isus typical to 20uA and 220uA
Added section 3.9.3 on suspend current considerations
*C
484726
See ECN
ARI
Removed all references the part number CY7C68055. Corrected the bullet in
Features to state that 24 GPIO’s are available. Added the Test ID (TID#) to the
Features on the front page. Made changes to the block diagram on the first page
(this is now a Visio drawing instead of a Framemaker drawing). Corrected the
Ambient Temperature with Power Supplied. Moved figure titles to meet the new
template. Checked grammar. Took out 9-bit address bus from the block diagram on
the first page. Corrected Figure 4.1
*D
492009
See ECN
OSG
Added Icc data in DC Characteristics and Maximum Power dissipation
*E
500408
See ECN
OSG
Changed ESD spec to 1500V
*F
502115
See ECN
OSG
Changed ESD spec to 2000V and 1500V only for SCL and SDA pins.
Added min spec for tOEoff
Changed Icc and power dissipation numbers
*G
1128404
See ECN
*H
1349903
See ECN
AESA
Section 7 - Changed -0°C to -40°C
*I
2728476
07/02/09
ODC
Deleted Note on AVcc parameter in DC Characteristics table
Document # 001-06120 Rev *I
OSG/ARI Removed SLCS from figure in Section 9.6 Slave FIFO Asynchronous Write
Changed SLWR Pulse HIGH parameter to 50ns
Section 9.13.1 - Removed the indication that SLCS and SLRD can be asserted
together
Section 9.13.3 - Removed the indication that SLCS and SLRD can be asserted
together
Implemented the latest template.
Page 39 of 40
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CY7C68053
Sales, Solutions, and Legal Information
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© Cypress Semiconductor Corporation, 2006-2009. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of
any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for
medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as
critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems
application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign),
United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of,
and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress
integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without
the express written permission of Cypress.
Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not
assume any liability arising out of the application or use of any product or circuit described herein. Cypress does not authorize its products for use as critical components in life-support systems where
a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress’ product in a life-support systems application implies that the manufacturer
assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Use may be limited by and subject to the applicable Cypress software license agreement.
Document # 001-06120 Rev *I
Revised July 02, 2009
Page 40 of 40
Purchase of I2C components from Cypress, or one of its sublicensed Associated Companies, conveys a license under the Philips I2C Patent Rights to use these components in an I2C system, provided
that the system conforms to the I2C Standard Specification as defined by Philips. MoBL-USB FX2LP18, EZ-USB FX2LP and ReNumeration are trademarks, and MoBL-USB is a registered trademark,
of Cypress Semiconductor Corporation. All product and company names mentioned in this document are the trademarks of their respective holders.
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