PTC PT6554

PT6554
LCD Driver IC
DESCRIPTION
PT6554 is a high performance Liquid Crystal Display
(LCD) Driver IC utilizing CMOS technology specially
designed with Key Input function. It can drive up to a
maximum of 164 segments and control up to 4 general
purpose output ports. It includes a Key Scan Circuit
that can support up to 30 key inputs and provides
On-Chip Voltage Detection Type Reset Circuit which
prevents incorrect display. Display Data can be
directly displayed without using any decoder. PT6554
also supports both 1/4 duty-1/2 bias and 1/4 duty-1/3
bias drive techniques. Pin assignments and
application circuit are optimized for easy PCB Layout
and cost saving advantages.
FEATURES
•
•
•
•
•
•
•
•
•
CMOS technology
Up to 164 segment drivers (4 Com x 41 Seg)
Up to 4 general purpose output ports
Key input function
1/4 duty-1/2 bias and 1/4 duty-1/3 bias drive
techniques
Sleep mode & all segment OFF function
On-Chip voltage detection type reset circuit
RC oscillation circuit
Available in 64 pins, QFP or LQFP package
APPLICATION
• Electronic equipment with LCD display
BLOCK DIAGRAM
Tel: 886-66296288‧Fax: 886-29174598‧ http://www.princeton.com.tw‧2F, 233-1, Baociao Road, Sindian, Taipei 23145, Taiwan
PT6554
APPLICATION CIRCUITS
Notes:
1. A capacitor must be added to the power line so that both the power supply voltage (VDD) rise time when power is applied and the power supply
voltage (VDD) fall time when power drops are at least 1ms.
2. DO is an open – drain output and requires a pull-high resistor between 1KΩ to 10KΩ. The pull-up resistor value must be appropriate to the capacitor
of the external wiring so that the signal wave forms are not degraded.
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PT6554
Notes:
1. A capacitor must be added to the power line so that both the power supply voltage (VDD) rise time when power is applied and the power supply
voltage (VDD) fall time when power drops are at least 1ms.
2. DO is an open – drain output and requires a pull-high resistor between 1KΩ to 10KΩ. The pull-up resistor value must be appropriate to the capacitor
of the external wiring so that the signal wave forms are not degraded.
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PT6554
Notes:
1. A capacitor must be added to the power line so that both the power supply voltage (VDD) rise time when power is applied and the power supply
voltage (VDD) fall time when power drops are at least 1ms.
2. DO is an open-drain output and requires a pull-high resistor between 1KΩ to 10KΩ. The pull-up resistor value must be appropriate to the capacitor
of the external writing so that the signal wave forms are not degraded.
3. R1=R2=R3, the resistance value must be decide by the LCD panel size.
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PT6554
ORDER INFORMATION
Valid Part Number
PT6554
PT6554LQ
Package Type
64 Pin, QFP
64 Pin, LQFP
Top Code
PT6554
PT6554LQ
PIN CONFIGURATION
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PT6554
PIN DESCRIPTION
Pin
Pin No.
SG1/P1 to
SG4/P4
SG5 to SG39
1 to 4
5 to 39
COM1
COM2
COM3
COM4
40
41
42
43
KS1/SG40,
KS2/SG41,
KS3 to KS6
44
45
46 to 49
KI1to KI5
50 to 54
OSC
60
CE
CLK
DI
62
63
64
DO
61
TEST
55
VDD1
57
VDD2
58
VDD
56
VSS
59
V1.4
Active
I/O
Handling
when unused
Segment outputs for displaying the display data
transferred by serial data input.
The SG1/P1 to SG4/P4 pins can be used as
general-purpose output ports under serial data control.
-
O
Open
Common driver outputs
The frame frequency fO is given by: fO=(fosc/512)Hz
-
O
Open
-
O
Open
H
I
GND
-
I/O
VDD
H
I
I
I
GND
O
Open
-
I
-
-
I
Open
-
I
Open
-
-
-
-
-
-
Function
Key scan outputs
Although normal key scan timing lines require diodes to
be inserted in the timing lines to prevent shorts, since
these outputs are unbalanced CMOS transistor outputs,
these outputs will not be damaged by shorting when
these outputs are used to from a key matrix. The
KS1/SG40 and KS2/SG41 pins can be used as segment
outputs when so specified by the control data
Key scan inputs.
These pins have built-in pull-down resistors.
Oscillator connection.
An oscillator circuit is formed by connecting an external
resistor and capacitor at this pin.
Serial data interface connections to the controller. Note
that DO, being an open-drain output, requires a pull-up
resistor.
CE: Chip enable
CLK: Synchronization clock
DI: Transfer data
DO: Output data
This pin must be connected to ground.
Used for applying the LCD drive 2/3 bias voltage
externally. Must be connected to VDD1 when a 1/2 bias
drive scheme is used.
Used for applying the LCD drive 1/3 bias voltage
externally. Must be connected to VDD1 when a 1/2 bias
drive scheme is used.
Power supply connection. Provide a voltage of between
4.5 and 6.0V
Power supply connection. Connect to ground.
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PT6554
INPUT/OUPUT CONFIGURATIONS
The schematic diagrams of the input and output circuits of the logic section are shown below:
INPUT PIN: CLK, CE, DI
INPUT PIN: KI1 TO KI5
OUTPUT PIN: DO
OUTPUT PIN: KS3 TO KS6
OUTPUT PIN: SG1/P1 TO SG4/P4, SG5 TO SG39,
S40/KS1, S41/KS2
OUTPUT PIN: COM1 TO COM4
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PT6554
FUNCTION DESCRIPTION
CONTROL DATA BITS
SLEEP CONTROL BITS: S0, S1
S0 and S1 are control bits used to select either the Normal or Sleep Mode as well as set the state of the key scan output
pins, namely: KS1 to KS6 during the key scan stand-by. Please refer to the table below.
Control data
Output pin states during key scan stand-by
OSC
Segment outputs
Mode
controller
Common outputs
S0
S1
KS1
KS2
KS3
KS4
KS5
KS6
0
0
Normal
Operating
Operating
H
H
H
H
H
H
0
1
Sleep
Stopped
L
L
L
L
L
L
H
1
0
Sleep
Stopped
L
L
L
L
L
H
H
1
1
Sleep
Stopped
L
H
H
H
H
H
H
Note: This table is under the assumption that the pins – SG40/KS1 and SG41/KS2 are used as Key Scan Output Pins.
KEY SCAN OUTPUT / SEGMENT DRIVER OUTPUT SELECT BIT: K0, K1
K0 and K1 are control bits used to select the function of the pins – SG40/KS1 and SG41/KS2.
These pins (SG40/KS1 and SG41/KS2) may either be used as Key Scan Output Pins or Segment Driver Output Pins.
Please refer to the following table.
Control data
Output pin state
Maximum number of input keys
K0
K1
SG40/KS1
SG41/KS2
0
0
KS1
KS2
30
0
1
SG40
KS2
25
1
X
SG40
SG41
20
Note: x = Not Relevant
SEGMENT DRIVER OUTPUT / GENERAL PURPOSE OUTPUT PORT SELECT BIT:
P0, P1
P0 and P1 are control bits used to select the function of the pins – SG1/P1 to SG4/P4. These pins (SG1/P1 to SG4/P4)
may be used either as Segment Driver Output Pins or General Purpose Output Ports. Please refer to the table below.
Control data
P0
P1
0
0
0
1
1
0
1
1
SG1/P1
SG1
P1
P1
P1
Output state
SG2/P2
SG3/P3
SG2
SG3
P2
SG3
P2
P3
P2
P3
SG4/P4
SG4
SG4
SG4
P4
When the output pins (SG1/P1 to SG4/P4) are used as General Output Ports, the correspondence between the display
data and these pins are shown in the table below.
Output pin
SG1/P1
SG2/P2
SG3/P3
SG4/P4
Corresponding display data
D1
D5
D9
D13
To further clarify the table above, the following example is given. If the output pin – SG1/P1 is used as a General Output
Port, then SG1/P1 Pin will output a “HIGH” Level if the corresponding Display Data,
D1 – is set to “1”. Likewise, if the output pin – SG4/P4 is used as a General Output Port, then the SG4/P4 Pin will output
“HIGH” Level, if the corresponding Display Data, D13 – is set to “1”.
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PT6554
SEGMENT ON / OFF CONTROL BIT: SC
SC is the control bit used to control the state (ON or OFF) of the Segment Drivers. Please refer to the table below. It
should be noted that turning OFF the Segment by setting SC Bit means that the Segments are turned OFF by outputting
segment OFF waveforms from the Segment Driver Output Pins.
SC
0
1
Display state
On
Off
1/2 BIAS OR 1/3 BIAS DRIVE TECHNIQUE SELECT BIT: DR
DR is the control bit used to select either the 1/2 or 1/3 Bias Drive Technique. Please refer to the table below.
DR
0
1
Drive scheme
1/3 bias drive
1/2 bias drive
KEY OUTPUT DATA BITS: KD1 TO KD30
KD1 to KD30 are key data bits of the key matrix formed by the KS1 to KS6 lines and the KI1 to KI5 lines. Please refer to
the table below for the correspondence between the output pins – KS1 to KS6, input pins KI1 to KI5 and the Key Data
Bits KD1 to KD30.
KI1
KI2
KI3
KI4
KI5
KS1/SG40
KD1
KD2
KD3
KD4
KD5
KS2/SG41
KD6
KD7
KD8
KD9
KD10
KS3
KD11
KD12
KD13
KD14
KD15
KS4
KD16
KD17
KD18
KD19
KD20
KS5
KD21
KD22
KD23
KD24
KD25
KS6
KD26
KD27
KD28
KD29
KD30
Note: Output Pins – SG40/KS1 and SG41/KS2 are used as Key Scan Output Pins.
As stated earlier, key matrix having up to a maximum of 30 keys may be constructed using the KS1 to KS6 and KI1 to
KI5 lines. If any one of the keys is pressed, the corresponding key output data is set to 1. For example, the key data bit,
KD23 is set to “1”, when the corresponding key is pressed.
If the output pins, SG40/KS1 and SG41/KS2 are used as Segment Driver Output Pins (by setting the K1 and K0 control
bits), a key matrix having up to a maximum of 20 keys may be constructed using the KS3 to KS6 and KI1 to KI5 lines.
The key output data bits KD1 to KD10 are set to 0.
SLEEP ACKNOWLEDGE DATA BIT: SA
SA is an output data bit that is used to set the state when the key is pressed. When DO is in “LOW” state and the serial
data is inputted, then the mode can be set either to Normal or Sleep Mode during this period. SA will be “1” in sleep mode
and “0” in normal mode.
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PT6554
DISPLAY DATA & OUTPUT PIN CORRESPONDENCE
Output
SG1/P1
SG2/P2
SG3/P3
SG4/P4
SG5
SG6
SG7
SG8
SG9
SG10
SG11
SG12
SG13
SG14
SG15
SG16
SG17
SG18
SG19
SG20
COM1
D1
D5
D9
D13
D17
D21
D25
D29
D33
D37
D41
D45
D49
D53
D57
D61
D65
D69
D73
D77
COM2
D2
D6
D10
D14
D18
D22
D26
D30
D34
D38
D42
D46
D50
D54
D58
D62
D66
D70
D74
D78
COM3
D3
D7
D11
D15
D19
D23
D27
D31
D35
D39
D43
D47
D51
D55
D59
D63
D67
D71
D75
D79
COM4
D4
D8
D12
D16
D20
D24
D28
D32
D36
D40
D44
D48
D52
D56
D60
D64
D68
D72
D76
D80
Output pin
SG21
SG22
SG23
SG24
SG25
SG26
SG27
SG28
SG29
SG30
SG31
SG32
SG33
SG34
SG35
SG36
SG37
SG38
SG39
KS1/SG40
KS2/SG41
COM1
D81
D85
D89
D93
D97
D101
D105
D109
D113
D117
D121
D125
D129
D133
D137
D141
D145
D149
D153
D157
D161
COM2
D82
D86
D90
D94
D98
D102
D106
D110
D114
D118
D122
D126
D130
D134
D138
D142
D146
D150
D154
D158
D162
COM3
D83
D87
D91
D95
D99
D103
D107
D111
D115
D119
D123
D127
D131
D135
D139
D143
D147
D151
D155
D159
D163
COM4
D84
D88
D92
D96
D100
D104
D108
D112
D116
D120
D124
D128
D132
D136
D140
D144
D148
D152
D156
D160
D164
To provide further clarity, an example is given in the table below showing the SG11 – Segment Driver Output State and
its corresponding Display Data – D41, D42, D43, D44 relationship.
D41
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
V1.4
Display data
D42
D43
0
0
0
0
0
1
0
1
1
0
1
0
1
1
1
1
0
0
0
0
0
1
0
1
1
0
1
0
1
1
1
1
D44
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
Output pin state
SG11
The LCD segments for COM1, COM2, COM3 and COM4 are off.
The LCD segment for COM4 is on.
The LCD segment for COM3 is on.
The LCD segments for COM3 and COM4 are on.
The LCD segment for COM2 is on.
The LCD segments for COM2 and COM4 are on.
The LCD segments for COM2 and COM3 are on.
The LCD segments for COM2, COM3 and COM4 are on.
The LCD segment for COM1 is on.
The LCD segments for COM1 and COM4 are on.
The LCD segments for COM1 and COM3 are on.
The LCD segments for COM1, COM3 and COM4 are on.
The LCD segments for COM1 and COM2 are on.
The LCD segments for COM1, COM2 and COM4 are on.
The LCD segments for COM1, COM2 and COM3 are on.
The LCD segments for COM1, COM2, COM3 and COM4 are on.
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PT6554
SERIAL DATA INPUT
CASE 1: CLK IS TERMINATED AT “LOW” LEVEL
Notes:
1. Address: 42H
2. Display Data Bits: D1 to D164
3. Sleep Control Data: S0, S1
4. Key Scan Output / Segment Driver Output Select Bits: K0, K1
5. Segment Driver Output / General Purpose Output Port Select Bits: P0, P1
6. Segment ON / OFF Control Bit: SC
7. 1/2 Bias or 1/3 Bias Drive Select Bit: DR
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PT6554
CASE 2: CLK IS TERMINATED AT “HIGH” LEVEL
Notes:
1. Address: 42H
2. Display Data Bits: D1 to D164
3. Sleep Control Data: S0, S1
4. Key Scan Output / Segment Driver Output Select Bits: K0, K1
5. Segment Driver Output / General Purpose Output Port Select Bits: P0, P1
6. Segment ON / OFF Control Bit: SC
7. 1/2 Bias or 1/3 Bias Drive Select Bit: DR
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PT6554
SERIAL DATA OUTPUT
CASE 1: CLK IS TERMINATED AT “LOW” LEVEL
Notes:
1. Address: 43H
2. Key Output Data Bits: KD1 to KD30
3. Sleep Acknowledge Bit: SA
4. If the Key Data Read Operation is executed when DO is in “HIGH” state, then the Read Key Data Bits (KD1 to KD30) and the Sleep Acknowledge
Bit (SA) will not be valid.
CASE 2: CLK IS TERMINATED AT “HIGH” LEVEL
Notes:
1. Address: 43H
2. Key Output Data Bits: KD1 to KD30
3. Sleep Acknowledge Bit: SA
4. If the Key Data Read Operation is executed when DO is in “HIGH” state, then the Read Key Data Bits (KD1 to KD30) and the Sleep Acknowledge
Bit (SA) will not be valid.
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PT6554
SLEEP MODE
The Sleep Mode is enabled when any one of the Sleep Acknowledge Control Bits – S0 or S1 is set to “1”. Under the
Sleep Mode, the all the segment and common driver outputs are set to “LOW” level and the oscillation operation is
terminated. Oscillation operation will only commence again if a key is pressed. Please note that this reduces power
dissipation. The Sleep Mode is cleared when both control bits – S0 and S1 are set to “0”.
It should be noted, however, that the output pins – SG1/P1 and SG2/P2 might still be used as General Purpose Output
Ports by setting the control bits – P0 and P1 even under the Sleep Mode. In other words, the Sleep Mode does not in
anyway affect the SG1/P1 and SG2/P2 pins from being used as General Purpose Output Ports.
KEY SCAN OPERATION
KEY SCAN TIMING
PT6554 scans the keys twice (reads the key data twice) and if the key data matches, this key is defined as PRESSED (or
ON ). A key scan period is equivalent to 384T (s). 800T (s) after the key scan commences, PT6554 outputs a key data
read request. If the key data from the does not match and a key was pressed at that point, the keys are scanned again.
It must be noted that PT6554 cannot detect a key which is pressed shorter than 800T (s).
Notes:
1. T=1/fosc where fosc=oscillation frequency
2. The Sleep Mode, the state of these pins is determined by the control bits – S0 and S1. Key Scan signals are not outputted from pins that are set to
“LOW” Level.
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PT6554
KEY SCAN OPERATING UNDER THE NORMAL MODE
Under the Normal Mode, the Key Scan Output Pins – KS1 to KS6 are set to HIGH. When a key is pressed, a key scan
operation commences. The keys are scanned until all keys are released. For multiple key press operation, a multiple key
press is valid only if multiple key data bits have set and verified by the key scan.
If a key is pressed longer than 800T(s), PT6554 outputs a key read data request (DO is set to “LOW” level) to the
controller. The controller acknowledges the request and reads the key data. It must be noted that if CE is HIGH during a
serial data transfer, then DO is set to “HIGH”.
After the controller reads the key data, the key data request is cleared (DO is set to HIGH) and another key scan
operation is performed.
Notes:
1. T=1/fosc, where fosc is the oscillation frequency.
2. DO is an open – drain output and requires a pull-high resistor between 1KΩ to 10KΩ.
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PT6554
KEY SCAN OPERATION UNDER THE SLEEP MODE
Under the Sleep Mode, the key scan output pins – KS1 to KS6 are set either to HIGH or LOW” State by the Sleep
Acknowledge Control Bits – S0 and S1. If a key that is located on one of the lines corresponding to a KS1 to KS6 pin that
has been set to “HIGH” is pressed, then the oscillation commences and the key scan operation is executed. The keys
are scanned until all keys are released. For multiple key press operation, a multiple key press is valid only if multiple key
data bits have been set and verified by the key scan.
If a key is pressed longer than 800T (s), PT6554 outputs a key read data request (DO is set to LOW” level) to the
controller. The controller acknowledges the request and reads the key data. It must be noted that if CE is “HIGH” during
a serial data transfer, then DO is set to “HIGH”.
After the controller reads the key data, the key data request is cleared (DO is set to “HIGH”) and another key scan
operation is performed. It must be noted that the Sleep Mode is not cleared. Please refer to the Sleep Mode Key Scan
example given below.
In the example below, Sleep Mode: S0=0, S1=1, KS6 Pin=”HIGH”.
Notes:
1. T=1/fosc, where fosc is the oscillation frequency.
2. In order to prevent erroneous operation due to sneak current in the KS6 scan output signal when keys on the KS1 to KS5 lines are pressed at the
same time, diodes must be connected as shown in the diagram above.
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PT6554
Note: DO is an open - drain output and requires a pull-high resistor between 1KΩ to 10KΩ.
KEY SCAN OPERATION FOR MULTIPLE KEY PRESSES
For dual key press operation, PT6554 can perform key scan operations without any need for a diode to be connected.
For triple key press on the KI 1 to KI5 lines, multiple key presses on the KS1 to KS6 lines, and other multiple key presses
require a diode to be connected in series with each key. Connecting a diode will ensure that only the keys that were
pressed will be recognized. Applications that cannot determine triple or more multiple key presses must check the key
data for three or more 1 bit and ignore such data.
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PT6554
VOLTAGE DETECTION TYPE RESET CIRCUIT (VDET)
The Voltage Detection Type Reset Circuit generates an output signal and resets the system when power is applied for
the first time and when voltage drops (that is, for example, the power supply voltage is less than or equal to the power
down detection voltage (VDET=3.0V typ).) To ensure that this reset function works properly, it is recommended that a
capacitor be connected to the power supply line such that both the power supply voltage (VDD) rise time when power is
first applied and the power supply voltage (VDD) fall time when the voltage drops are at least 1ms.
SYSTEM RESET
If the supply voltage (VDD) rise time when power is first applied is at least 1ms, then the VDET output signal will initiate
a system reset when the supply voltage is increased. Likewise, if the supply voltage (VDD) fall time when power drops is
at least 1ms, then the VDET output signal will initiate a system reset when the supply voltage is decreased. It must be
noted that the reset function is cleared at the point when all the serial data (Display Data – D1 to D164 and the control
data) have been completely transferred. Please refer to the figure below.
Power supply voltage VDD rise time: t1 > 1ms
Power supply voltage VDD fall time: t2 > 1ms
During the reset period, the internal states of the various blocks of PT6554 are enumerated below. It should be noted
that the Address Interface, Control Register and the Shift Register Blocks are not reset during this period since serial
data transfer is possible. (Please also refer to the Block Diagram Section)
CLOCK GENERATOR BLOCK
When the reset function is applied, the base clock is terminated. The state of the OSC pin (either Normal or Sleep Mode)
is determined after the control bits – S0 and S1 have been transferred.
COMMON DRIVER, SEGMENT DRIVER & LATCH BLOCKS
When the reset function is applied the display is turned OFF. It should be noted, however, that the display data may be
inputted to the latch circuit during the reset period.
KEY SCAN BLOCK
When the reset function is applied, the key scan circuit is set to the initial state and the key scan operation is disabled.
KEY BUFFER BLOCK
When the reset function is applied, all the key data are set to “LOW”.
CONTROL REGISTER & SHIFT REGISTER
Since serial data transfer is possible, these circuits are not reset.
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PT6554
During the reset period the states of the output pins are listed in the table below.
Output pin
SG1/P1 to SG4/P4
SG5 to SG39
COM1 to COM4
KS1/SG40, KS2/SG41
KS3 to KS5
KS6
DO
State during reset
L (Note 1)
L
L
L (Note 1)
X (Note 2)
H
H (Note 3)
Notes:
1. x = Not Relevant
2. These output pins are forcibly set to be used as Segment Driver Output Pins and are held at “LOW” State.
3. When power is first applied, these pins are not defines until the control bits – S0 and S1 have been completely transferred.
4. DO is an open - drain output and requires a pull-high resistor between 1KΩ to 10KΩ. It is kept at “HIGH” state during the reset period even if a key
data read operation is executed..
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PT6554
1/4 DUTY, 1/2 BIAS DRIVE TECHNIQUE
V1.4
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PT6554
1/4 DUTY, 1/3 BIAS DRIVE TECHNIQUE
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PT6554
CONTROLLER KEY DATA READ TECHNIQUES
When the controller receives a key data read request from PT6554, it performs a key data read acquisition operation
using either the Timer Based Key Data Acquisition or the Interrupt Based Key Data Acquisition.
TIMER BASED KEY DATA ACQUISITION TECHNIQUE
Under the Timer Based Key Data Acquisition Technique, the controller uses a timer to determine the states of the keys
(ON or OFF) and read the key data. Please refer to the flowchart below.
Every t7 period, the controller checks the state of DO when the CE is at “LOW” level. If DO is “LOW”, then the controller
validates that a key has been pressed and performs a key data read operation. Please refer to the timing diagram below.
It must be noted that if the key data read operation is performed when the DO is “HIGH”, the read key data (KD1 to KD30)
and the sleep acknowledge bit will not be valid.
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PT6554
INTERRUPT BASED KEY DATA ACQUISITION TECHNIQUE
Under the Interrupt Based Key Data Acquisition Technique, the controller uses interrupts to determine the state of the
keys (ON or OFF) and read the key data. Please refer to the flow chart diagram below.
Every t8 period, the controller checks the state of the DO Pin when CE is at “LOW” state. If the DO is at “LOW” level, then
the controller validates that a key has been pressed and a key data read operation is performed. Please refer to the
timing diagram below. It must be noted however, that if a key data read operation is performed when DO is held “HIGH”,
the read key data – KD1 to KD30 and the sleep acknowledge bit SA will not be valid.
Notes:
1. t8 > t4
2. t3 is the Key Scan Execution Time when the key data matches (2 key scan operations): 800T (s)
3. t4 is the Key Scan Execution Time when the key data do not match (2 key scan operations) and the key scan operation is once again performed:
1600T (s).
4. T=1/fosc where fosc is the oscillation frequency.
5. t5 is the Key Address Transfer Time (43H)
6. t6 is the Key Data Read Time
7. T7 > (t5 + t6 + t4)
V1.4
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June 2010
PT6554
ABSOLUTE MAXIMUM RATINGS
(Unless otherwise specified, Ta=25℃, Vss=0V)
Parameter
Symbol
Conditions
Maximum supply voltage
VDDmax VDD
VIN1
CE, CLK, DI
Input voltage
OSC, KI1 to KI5, TEST, VDD1,
VIN2
VDD2
VOUT1 DO
Output voltage
OSC, SG1 to SG41, COM1 to
VOUT2
COM4, P1 to P4
IOUT2 SG1 to SG41
IOUT3 COM1 to COM4
Output current
IOUT4 KS1 to KS6
IIN1
P1 to P4
Allowable power dissipation
Pd max Ta = 85℃
Operating temperature
Topr
Storage temperature
Tstg
Rating
-0.3 to +7.0
-0.3 to +7.0
Unit
V
V
-0.3 to VDD +0.3
V
-0.3 to +7.0
V
-0.3 to VDD +0.3
V
300
3
1
5
200
-40 to +85
-65 to +150
μA
mA
mA
mA
mW
℃
℃
Typ.
Unit
V
V
V
V
V
V
ALLOWABLE OPERATING CONDITIONS
(Unless otherwise specified, Ta=25℃, Vss=0V)
Parameter
Symbol
Conditions
Supply voltage
VDD
VDD
VDD1
VDD1
Input voltage
VDD2
VDD2
VIH1
CE, CLK, DI
Input high level voltage
VIH2
KI1 to KI5
Input low level voltage
VIL
CE, CLK, DI, KI1 to KI5
Recommended external
ROSC
OSC
resistance
Recommended external
COSC
OSC
capacitance
Guaranteed oscillation
fosc
OSC
range
Data setup time
tds
CLK, DI
Data hold time
tdh
CLK, DI
CE wait time
tcp
CE, CLK
CE setup time
tcs
CE, CLK
CE hold time
tch
CE, CLK
High level clock pulse
toH
CL
width
Low level clock pulse
toL
CL
width
Rise time
CE, CLK, DI
Fall time
CE, CLK, DI
DO output delay time
tdc
DO, RPU=4.7KΩ, CL=10pF*1
DO rise time
tdr
DO, RPU=4.7KΩ, CL=10pF*1
V1.4
24
Min.
4.5
2/3 VDD
1/3 VDD
0.8 VDD
0.6 VDD
0
25
Max.
6.0
VDD
VDD
6.0
VDD
0.2 VDD
62
KΩ
680
pF
50
100
KHz
160
160
160
160
160
ns
ns
ns
ns
ns
160
ns
160
ns
160
160
1.5
1.5
ns
ns
μs
μs
June 2010
PT6554
ELECTRICAL CHARACTERISTICS FOR THE
ALLOWABLE OPERATING CONDITIONS
(Unless otherwise specified, Ta=25℃, VSS=0V)
Parameter
Symbol
Conditions
Hysteresis
VH
CE, CLK, DI
Power-down
VDET
detection voltage
Input high level
IIH
CE, CLK, DI: VI=VDD
voltage
Input high level
IIL
CE, CLK, DI: VI=0V
current
Input floating voltage
VIF
KI1 to KI5
Pull-down resistance
RPD
KI1 to KI5: VDD=5.0V
Output off leakage
IOFFH
DO: VO=6.0V
current
VOH1
KS1 to KS6: IO=-500μA
VOH2
P1 to P4: IO=-1mA
Output high level
voltage
VOH3
SG1 to SG41: IO=-20μA
VOH4
COM1 to COM4: IO=-100μA
VOL1
KS1 to KS6: IO=25μA
VOL2
P1 to P4: IO=1mA
Output low level
VOL3
SG1 to SG41: IO=20μA
voltage
VOL4
COM1 to COM4: IO=100 μA
VOL5
DO: IO=1mA
COM1 to COM4:1/2 bias,
VMID1
IO=±100μA
SG1 to SG41:1/3 bias,
VMID2
IO=±20μA
SG1 to SG41:1/3 bias,
Output middle level
VMID3
voltage *2
IO=±20μA
COM1 to COM4:1/3 bias,
VMID4
IO=±100μA
COM1 to COM4:1/3 bias,
VMID5
IO=±100μA
Oscillator frequency
fosc
OSC:R=62KΩ, C=680pF
IDD1
Sleep mode
VDD=6.0V, output open,
IDD2
1/2 bias, fosc=50KHz
Current drain
VDD=6.0V, output open,
IDD3
1/3 bias, fosc=50KHz
Min.
Typ.
0.1 VDD
2.7
3.0
Max.
Unit
V
V
5.0
μA
-5.0
μA
0.05VDD
250
V
KΩ
6.0
μA
VDD -0.5
VDD -0.2
0.5
1.5
1.0
1.0
1.0
0.5
V
V
V
V
V
V
V
V
V
1/2VDD -1.0
1/2VDD +1.0
V
2/3VDD -1.0
2/3VDD +1.0
V
1/3VDD -1.0
1/3VDD +1.0
V
2/3VDD -1.0
2/3VDD +1.0
V
1/3VDD -1.0
1/3VDD +1.0
V
50
60
100
KHz
μA
250
500
μA
200
400
μA
50
VDD -1.2
VDD -1.0
VDD -1.0
VDD -1.0
0.2
100
0.1
40
Notes:
1. A capacitor must be added to the power line so that both the power supply voltage (VDD) rise time when power is applied and the power supply
voltage (VDD) fall time when power drops are at least 1 ms.
2. DO is an open – drain output and requires a pull-high resistor between 1KΩ to 10KΩ. The pull-up resistor value must be appropriate to the capacitor
of the external wiring so that the signal wave forms are not degraded.
V1.4
25
June 2010
PT6554
CASE 1: WHEN CLK IS TERMINATED AT LOW LEVEL.
CASE 2: WHEN CLK IS TERMINATED AT HIGH LEVEL.
The Bias Voltage Generation Driver built-into VDD1 and VDD2 are not included. Please refer to the diagram below.
V1.4
26
June 2010
PT6554
PACKING INFORMATION
64 PINS, LQFP PACKAGE
Symbol
A
A1
A2
b
c
D
D1
E
E1
e
L
L1
Min.
0.05
1.35
0.17
0.09
θ
0°
Nom.
1.40
0.22
12.00 BSC
10.00 BSC
12.00 BSC
10.00 BSC
0.50 BSC
0.60
1.00 REF
0.45
3.5°
Max.
1.60
0.15
1.45
0.27
0.20
0.75
7°
Notes:
1. All dimensions are in millimeter
2. Refer to JEDEC MS-026 BCD
V1.4
27
June 2010
PT6554
64 PINS, QFP PACKAGE
Symbol
A
A1
A2
b
c
D
D1
E
E1
e
L
L1
Min.
0.00
1.90
0.29
0.11
θ
0°
0.65
Nom.
0.35
17.20 BSC
14.00 BSC
17.20 BSC
14.00 BSC
0.80 BSC
1.60 REF
Max.
3.15
0.25
2.90
0.41
0.23
-
8°
1.05
Notes:
1. Refer to JEDEC MC-022BE
2. All dimensions are in millimeter
V1.4
28
June 2010
PT6554
IMPORTANT NOTICE
Princeton Technology Corporation (PTC) reserves the right to make corrections, modifications, enhancements,
improvements, and other changes to its products and to discontinue any product without notice at any time.
PTC cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a PTC product. No
circuit patent licenses are implied.
Princeton Technology Corp.
2F, 233-1, Baociao Road,
Sindian, Taipei 23145, Taiwan
Tel: 886-2-66296288
Fax: 886-2-29174598
http://www.princeton.com.tw
V1.4
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June 2010
PT6554
REVISION HISTORY
Date
1/10/2002
4/ 2002
10/ 2002
Revision No.
PT6554 pre1
PT6554 pre1.1
PT6554 v1.0
4/2004
PT6554 V1.1
09/02/2005
PT6554 V1.2
10/27/2006
PT6554 V1.3
06/15/2010
V1.4
PT6554 V1.4
Reference No.
for JJ
for JJ
Approval #:021004
Request No.:040323
Approval No.:040406
Modification No.:040405
Approval No.: 050901
Modification No.: 050901
Approval No.: 061008
Modification No.: 061007
Modification
New format
Modify
P25, “ Electrical Characteristics for the allowable
operating condition” : Input high level voltage
MAC1006010
30
June 2010