FAIRCHILD USB100

January 1999
USB100
Programmable Low-Cost USB Machine (PLUM)
Single Chip Controller for Mouse, Trackball, Joystick and Gamepad Applications
General Description
Features
The USB100 is a Low cost, fully customizable controller for USB
HID-class pointing devices. It is in full compliance with REV 1.0
of the USB standard and implements the HID class specification
for mice, trackballs, joysticks and gamepads. This device interprets the commands specified in the HID class document and
provides appropriate responses from an On-Chip EEPROM. It
also provides ability to customize the device according to individual needs of the designers. Programming utilities supplied with
this device allow HID manufacturers to easily create the necessary data to be programmed into the device.
■ USB 1.0 standard compliant
■ Has the necessary on-chip transceivers
■ Support for 2D and 3D mice with 2, 3 or more buttons
■ Supports 3 potentiometer mechanisms for joysticks
■ Up to 16 buttons for digital gamepads
■ Choice of 18-pin and 24-pin packages
■ Choice of 2Kbit and 4Kbit EEPROM densities
The device includes the necessary transceiver for USB operation
and meets all of the active and standby current specifications for
a bus-powered device.
Block Diagram
POWER
USB
COMMAND
PROCESSOR
(HID)
TX-FIFO
SERIAL
INTERFACE
ENGINE
X
C
V
R
USB CABLE
(D+, D-,
POWER &
GROUND)
RX-FIFO
STATE MACHINE
EEPROM
UP TO 3 ROLLER/
POTENTIOMETER
MECHANISMS
UP TO 16 BUTTONS
Use "A Diagram Number" Style Sheet"
USB100 rev.D
© 1999 Fairchild Semiconductor Corporation
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USB100 Programmable Low-Cost USB Machine (PLUM)
PRELIMINARY
24 Pin Package
OSC1
OSC2
H4
B8/F
RESET
H3
H1
H2
V1
V2
O2
GND
18 Pin 3D Package
OSC2
H4
F
RESET
H3
H1
H2
V1
V2
VDD
B6
USBD+
USBDGND
B7
B5
B1
B2
B3
B4
O1
OSC1
VDD
USBD+
USBDGND
B1
B2
B3
O1
Pin Description
Pin
Type
Description
H4
I
Roller/Button/Joystick input.
H3
I
Roller/Button/Joystick input.
O2
I/O
OSC1
I
Crystal input number 1.
Register output pin / Button input.
OSC2
I
Crystal input number 2
B4
I
Button input
Reset
I
Active high reset pin
H1
I
Roller/Button/Joystick input.
H2
I
Roller/Button/Joystick input.
V1
I
Roller/Button/Joystick input.
V2
I
Roller/Button/Joystick input.
GND
I
Ground
B7
I
Button input
B6
I
Button input
B5
I
Button input
VDD
I
Positive power supply
USBD+
O
USB D + line
USBD-
O
USB D – line
GND
I
Ground
B8/F
I/O
B1/CS
I
Button input / LED driver
Button input and chip select to internal
EEPROM.*
B2/SK
I
Button input and system clock to internal
EEPROM.*
B3/DI
I
Button input and data in to internal
EEPROM.*
O1/DO
O
Button input and data out to read from
internal EEPROM.*
* See Programming internal EEPROM section
USB100 rev.D
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USB100 Programmable Low-Cost USB Machine (PLUM)
Pinout
Operating Conditions
Ambient Storage Temperatures
-65°C to + 150°C
Ambient Operating Temperature
All Input or Output Voltages with
respect to ground
VCC + 1 to – 0.3V
Power Supply (VCC) Range
Lead Temperature
(Soldering, 10 seconds)
+300%
ESD Rating
2000V
0°C to +70°C
4.4V to 5.5V
DC and AC Electrical Characteristics 4.4V ≤ VCC ≤ 5.5V
Symbol
Parameter
Conditions
Min
Max
Units
ICCA
Operating Current
USB interface in active mode
40
mA
ICCS
Standby Current
USB interface in suspend
500
µA
VIL
Input Low Voltage
VIH
Input High Voltage
VOL
Output Low Voltage
VOH
Output High Voltage
0.8
2
V
V
0.4
2.4
V
V
IIL
Input Leakage Current
2.5
µA
IOL
Output Leakage Current
2.5
µA
1
MHz
FSK
SK Clock Frequency
TSKH
SK High Time
Note 3
250
0
ns
TSKL
SK Low Time
250
ns
TCS
Minimum CS Low Time
250
ns
TCSS
CS Setup Time
50
ns
TDH
DO Hold Time
70
ns
Note 4
TDIS
DI Setup Time
100
ns
TCSH
CS Hold Time
0
ns
TDIH
DI Hold Time
20
ns
TPD1
Output Delay to “1”
500
ns
TPD0
Output Delay to “0”
500
ns
TSY
CS to Status Valid
500
ns
TDF
CS to DO in TRI-STATE
100
ns
TWP
Write Cycle Time
10
ms
AC Test Conditions
Output Load
Input Pulse Levels
Timing Measurements Reference Level
1 TTL Gate
Input
0.4V and 2.4V
Output
1V and 2V
0.8V and 2.0V
Note 1: Stress ratings above those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and operation of the
device at these or any other conditions above those indicated in the operational sections of the specification is not implied. Exposure to absolute maximum rating conditions for
extended periods may affect device reliability.
Note 2: The shortest allowable S clock period = 1/fSK (as shown under the fSK parameter). Maximum SK clock speed (minimum SK period) is determined by the interaction of
several AC parameters stated in the datasheet. Within this SK period, both tSKH and tSKL limits must be observed. Therefore, it is not allowable to set 1/fSK = tSKH(minimum) +
tSKL(minimum) for shorter SK cycle time operation.
Note 3: CS (Chip Select) must be brought low (to VIL) for an interval of tCS in order to reset all internal device registers (device reset) prior to beginning another opcode cycle.
(This is shown in the opcode diagrams in the following pages.)
USB100 rev.D
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USB100 Programmable Low-Cost USB Machine (PLUM)
Absolute Maximum Ratings
O1, O2 Functionality. ICB register 1[3:2]
H1, H2, H3, H4, V1, V2 (Roller/Joystick inputs)
IOM[1:0]
Function
When configured as roller inputs these pins function in pairs, H1
and H2, H3 and H4, V1 and V2 to allow photo diodes to be
attached in a mouse or trackball application. See the section
“Roller Movement Reporting” for a more detailed description.
When configured for a joystick only one of the inputs pairs is used.
A potentiometer is attached to track the movements of a joystick
lever. When these inputs are configured as buttons they all act
independently as active low button inputs. All of them have
internal pull-ups and debounce circuitry which can be programmed
using the ICB registers. These inputs also contain current sink
features so no external resistor is needed to sink current from the
photo diode.
00
Both O1 and O2 function as programmable
outputs.
01
O1 is a programmable output but O2 is a
standard button input.
11
Both O1 and O2 are standard inputs.
In case these are selected as outputs, their state (1 or 0) can be
set using the USB set_report command. These outputs are opencollector. A typical use of these outputs is using them to drive LEDs
(for example, a drag-lock function in a trackball). These pins have
a programmable current sink capability.
B1, B2, B3, B4, B5, B6, B7, B8/F (Button inputs)
B8/F
The button inputs to the USB100 have internal pull up resistors,
with active low inputs to the chip. These inputs also contain
debounce circuitry which can be programmed by the ICB registers.
When this pin is configured as an input it will behave as a standard
button input. But if the pin is disabled in the ICB registers then this
pin can be used to control the roller LEDS in powersave mode.
Using the B8/F pin to control the LEDs
Key Debounce Select Table (ICB register3[3:2])
VDD
KD[1:0]
00
15 ms
01
30 ms
10
45 ms
11
60 ms
USB100
F
USBD -, USBD +
This allows the LEDs to be shut off during powersave mode which
allows the USB100 to draw very little current. The official name for
powersave mode on a USB device is known as suspend mode
which is discussed in the section labeled Suspend Mode Operation.
These inputs are the serial bus lines which USB data is communicated. These bi – directional lines connect to the host, through
a USB type A or type B connector, and are used to communicate
all USB information to and from the host. The two lines must both
be wired through a 27 ohm resistor before being attached to the
USB connector. See Recommended Configuration for a detailed
diagram.
OSC1, OSC2
These two pins are the clock inputs into the USB100. The speed
at which the chip runs at is 6MHz. The clock sign can be generated
two ways. The first is to use a parallel resonant, fundamental mode
crystal circuit or a ceramic resonator circuit connected to the
OSC1 and OSC2 inputs. The other method is to use a crystal
oscillator connected to the OSC2 input and leaving the OSC1
input unconnected
Reset
This pin is used to reset the entire chip. It must be held high for
more than 10ns, to reset the chip and then brought low for the reset
of normal chip operation.
O1, O2
USB modes of operation
These two pins are wired to internal registers which can be
programmed with either a “1” or a “0” by a USB request. If this
command is sent to the USB100. INSERT COMMAND FROM
INSPECTOR. Then the O1 and O2 pins will be programmed with
the values that are in the second data package. These two pins
can also be configured as standard button inputs by one of the ICB
registers.
USB100 rev.D
The USB100 loads up its configuration from the EEPROM on
power-on reset, or when a USB reset command is issued. Upon
completion of reset, the device is in a operational mode, and
responds correctly to the various commands described in the USB
spec rev 1.0. The USB100 supports two endpoints – the default
endpoint (endpoint 0) and the interrupt endpoint (endpoint 1). The
supported packet size on both endpoints is 8 bytes. The endpoint
1 is an “IN” endpoint.
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USB100 Programmable Low-Cost USB Machine (PLUM)
Interface Pin Descriptions
IS[3:0]
Current
The USB100 supports all of the required standard requests.
These requests are sent to the device using control transfers to
endpoint 0.
0000
0.1 mA
0001
0.2 mA
In USB terminology, the data transmitted by the mouse when
movement is detected is called a report. The reports are generated by the USB100 device in accordance to the USB HID spec
1.0 Final.
0010
0.3 mA
0011
0.4 mA
0100
0.5 mA
Programming the EEPROM
0101
0.6 mA
0110
0.7 mA
0111
0.8 mA
1000
0.9mA
1001
1.0mA
The on-chip EEPROM can be programmed in a special mode
which defines some of the button inputs/output as a microwire
port.. In this mode, these inputs behave as a conventional Microwire
serial port. Data can be easily programmed and verified, by
executing simple EEPROM programming commands.
Initial Configuration Bytes (ICB) register
description
Input Pin Configuration Byte 0 (ICB0) (Address 1)
The first five bytes in the EEPROM are used to configure the
physical characteristics of the USB100 device, and are called the
Initial configuration Byte registers. Some of the bits in these
registers are reserved, and are referred to as RFU (reserved for
future use) in the following section.
D6
D5
D4
IS3
IS2
IS1
IS0
D3
D2
IOM1 IOM0
D6
D5
D4
D3
D2
D1
D0
B8
B7
B6
B5
B4
B3
B2
B1
B[7:0]: Input Pin Report Generator. A ‘1’ causes this bit to be
reported in the corresponding report generated when the device
is polled for the status. The device accepts only the following bit
patterns as valid. B[7:0] control the functionality for pin inputs
B[8:1] respectively.
Roller Configuration Byte (Address 0)
D7
D7
D1
D0
00000000
R1
R0
00000001
R[1:0]: No of roller pairs. This pair of bits configure the functionality of the three roller pair inputs – <H1, H2>, <V1,V2> and <H3,
H4>.
00000011
00: No rollers on this device, all roller inputs are available as
general purpose inputs
00011111
01: H1, H2 are the only roller mechanism active. The other
roller inputs are available as general purpose inputs.
01111111
00000111
00001111
00111111
11111111
10: H1, H2 and V1 and V2 are defined as roller mechanism
pairs. The other pair is still available as general purpose
inputs.
Input Pin Configuration Byte 1 (ICB1) (Address 2)
11: All the three pairs of roller inputs function as roller inputs.
It must be noted that the reassignment of the rollers must be done
only as follows: If the application needs to use only one roller – use
H1 and H2. Two rollers – use H1, H2 and V1, V2, Three rollers –
use H1, H2, V1, V2 and H3, H4. Any other choice for roller use is
illegal and results in unpredictable device behavior.
D7
D6
D5
D4
D3
D2
D1
D0
IO1
IO0
EB5
EB4
EB3
EB2
EB1
EB0
EB[5:0]: Input Pin Report Generator, Extended byte. The functionality of this register is influenced by the roller configuration
byte. A ‘1’ causes this bit to be reported in the corresponding report
generated when the device is polled for the status. EB0 corresponds to H3 and EB1 corresponds to H4. EB2 corresponds to V1
and EB3 corresponds to V2. EB4 corresponds to H1 and EB5
corresponds to H2.
IOM[1:0]: I/O functionality of the O0 and O1 pins. When IOM0 is
set to ‘0’, the O0 bit functions as an output. When set to ‘1’ it
becomes an input. . When IOM1 is set to ‘0’, the O1 bit functions
as an output. When set to ‘1’ it becomes an input. The only valid
combinations for these bits are 00, 01 and 11 respectively.
00000000
00000001
00000011
IS[3:0]: This 4-bit value is to set the amount of current that an
external device can sink into the H1, H2, V1, V2 and H3 and H4
inputs When these bits are set to 0000 the current sink is set to 0.1
mA on each of the inputs. In can be varied in steps of 0.1mA up
to a max of 1 mA.
USB100 rev.D
00000111
00001111
00011111
00111111
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USB100 Programmable Low-Cost USB Machine (PLUM)
Standard Requests
Descriptor Setup
IO[1:0]: When the IO pins are reconfigured as inputs, a ‘1’ in the
corresponding bit position will cause the input to be included in the
report generator.
The EEPROM stores a Descriptor Description Table (DDT) followed by the actual descriptors (DES). The DDT begins at byte
address 8 in the EEPROM. It consists of 14 Words. Each Word
consists of two bytes – The first byte is a byte indicating the type
of descriptor (these byte values are indicated in the USB specification). The second byte is an address. This address indicates the
first byte of this descriptor in the EEPROM. An unimplemented
descriptor table entry begins with a 00. The following table shows
a possible configuration.
Application Configuration Byte (Address 3)
D7
D6
D5
D4
D3
D2
D1
D0
FIS3
FIS2
FIS1
FIS0
KD1
KD0
F1
F0
F[1:0]: Function Select. Selects between the following
Address Map
00 : Mouse operation
Memory AddressRange
01: RFU
10: Joystick Operation.
Data type
08-35
Descriptor Description Table
36-53
Device Descriptor
54-62
Config Descriptor
63-71
Interface Descriptor
10: 45 Ms
72-78
Mouse HID Class Descriptor
11: 60 Ms
79-86
Endpoint Descriptor
87-118
String Descriptor
11: Digital Gamepad operation
KD[1:0]: Key Debounce Select:
00: 15 Ms
01: 30 Ms
FIS[3:0]: These bits select the amount of current that the ‘F’ pin
can sink, in 1 mA increments. When FIS[3:0] = “0000” The current
sink is set at 2 mA. Incrementing this count by 1 will cause the
current to be increased by 1mA The maximum value is 10 mA.
Descriptor Description Table (for above example)
Remote Resume Config Byte (Address 4)
D7
D6
D5
D4
RFU
RFU
RFU
RFU
D3
D2
D1
D0
Address
Descriptor type
Memory Offset
08
Device
36
10
Config
54
12
Interface
63
14
Mouse-HID
72
16
Endpoint
78
18
String
87
20
00
00
22
00
00
24
00
00
26
00
00
28
00
00
30
00
00
011: 60 ms
32
00
00
100: 75 ms
34
00
00
RRES RRES RRES RRES
_EN
2
1
0
RRES_EN: Remote_resume enable. This bit, when set, enables
remote resume operation.
RRES[2:0]: Duration Select. When the device has entered in
suspend mode, these bits select the duration after which an
internal “momentary wakeup” is done to check whether there has
been any movement on the rollers in the mouse mode or the
potentiometers in the joystick mode. The RRES_EN bit must be
set to 1 to enable this feature.
000: 15 ms
001: 30 ms
010: 45 ms
101: 90 ms
Roller Movement Reporting
110: 105 ms
The roller mechanism built on the USB100 is capable of interfacing either to a LED-chopper wheel-Phototransistor system or a
mechanical system using a commutator with wiper contacts.
111: Reserved for future use (do not use this combination,
unpredictable operation could result)
USB100 rev.D
6
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USB100 Programmable Low-Cost USB Machine (PLUM)
RFU: Reserved for future use, must be set to 0.
USB100 Programmable Low-Cost USB Machine (PLUM)
H1 or V1 or H3
H2 or V2 or H4
Negative Counting
H1 or V1 or H3
H2 or V2 or H4
Positive Counting
v
USB100
Q1
D1
Q2
H1
D2
H2
F
Schematic 1: Roller Mode of Operation
Hardware Features
When the Roller configuration register is used to define an input
pair as roller inputs, the corresponding roller movement reporting
is enabled. In this case, internally, the roller wheel pulses are
counted and registered into an 8 bit register. One register is
available per input pair. A total of three rollers movement registers
(RMRs) are available, corresponding to the three roller mechanisms available. On all the input pairs (H1, H2 or V1, V2 or H3, H4)
the positive counting sequence is defined as (0,0), (0,1), (1,1) and
(0,0) and the same sequence repeating over again. Negative
counting sequence is defined as (0,0), (1,0), (1,1) and (0,1) and
the same sequence repeating again. Each of the above transitions
will result in the counter incrementing or decrementing by one
depending on whether the rollers are moving in the positive or
negative direction. Each time an IN query is sent on endpoint 1, the
counter contents are transferred to a temporary holding register
and queued for transmission on the USB. When an ACK is
received for the current transaction, the counter is cleared.
Roller / Potentiometer Interface
One of the key differences between the mouse and joystick
hardware implementation is that themouse uses optical encoding
v
P1
USB100
P2
H1
V1
Schematic 2 : Potentiometer Mode of
Operation for Joystick
USB100 rev.D
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Suspend mode operation
When the PLUM device determines that the necessary conditions
(laid down in the USB standard), it goes into the suspend mode.
It wakes up on USB bus activity, or when any of the buttons are
depressed. There exists an internal timer, whose timing operation
could be selected via bits 3 through 0 in ICB register 5. The PLUM
device wakes up on the expiration of the timer. It senses the roller/
potentiometer interface to determine if these inputs have changed
since the last poll. It does a remote wakeup, when such a
movement has occurred.
to set the bits. In a mouse mode, the H1, H2, V1,V2 and H3 & H4
inputs are selected for the roller mechanism decode.In the joystick
mode, it selects the potentiometer interface. The state machine
uses a different algorithm for interpreting the inputs to the chip.
This function selection also affects the format of the report that is
generated.The roller mode is shown in schematic 1 and the
potentiometer mode is shown in schematic 2.
In case of the roller mode of operation (mouse/trackball), the
transitions on the Hx and Vx pairs are used in the counting process
to generate a digital estimate of the motion of the ball. In the
joystick mode of operation, the RC timing constant changes the
width of an internal digital pulse whose width is measured and
reported back. All of the buttons feature an internal pullup. The
actual switches used is a push button switch with one terminal
connected to a button input and the second terminal connected to
ground.
Remote Wakeup Support
This device supports the remote wakeup feature. This is indicated
to the host via the corresponding descriptor. Internally, the state
machine uses the values of the RRES_EN and RRES[2:0] bits in
the Remote Resume configuration byte to enable this feature, and
the amount of time between the “polls” to the roller/potentiometer
ports to determine whether the necessary conditions for wakeup
have been met.
Crystal / Crystal Oscillator combination
OSC1
OSC2
The above configuration is the recommended configuration for
use with a crystal or a ceramic resonator. The capacitors are
optional and if used, must be in the 10-30pf range. The resistor is
necessary and its value is 1MΩ. A metal-can oscillator may be
used too. In this case, the output of the oscillator must be
connected to OSC1 and OSC2 must be left unconnected.
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approval of the President of Fairchild Semiconductor Corporation. As used herein:
1. Life support devices or systems are devices or systems which,
(a) are intended for surgical implant into the body, or (b) support
or sustain life, and whose failure to perform, when properly
used in accordance with instructions for use provided in the
labeling, can be reasonably expected to result in a significant
injury to the user.
Fairchild Semiconductor
Americas
Customer Response Center
Tel. 1-888-522-5372
2. A critical component is any component of a life support device
or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system,
or to affect its safety or effectiveness.
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USB100 rev.D
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USB100 Programmable Low-Cost USB Machine (PLUM)
and a roller wheel to detect mouse movement. In contrast, joystick
uses a potentiometer to detect angular motion. The function select
bits [F1:0] allow the designer