AD ADUC7129

Precision Analog Microcontroller
ARM7TDMI MCU with 12-Bit ADC and DDS DAC
ADuC7128/ADuC7129
FEATURES
In-circuit download, JTAG-based debug
Software triggered in-circuit reprogrammability
On-chip peripherals
2× UART, 2× I2C and SPI serial I/O
Up to 40-pin GPIO port
5× general-purpose timers
Wake-up and watchdog timers (WDT)
Power supply monitor
16-bit PWM generator
Quadrature encoder
Programmable logic array (PLA)
Power
Specified for 3 V operation
Active mode
11 mA (@ 5.22 MHz)
45 mA (@ 41.78 MHz)
Packages and temperature range
64-lead 9 mm × 9 mm LFCSP package, −40°C to 125°C
64-lead LQFP, −40°C to +125°C
80-lead LQFP, −40°C to +125°C
Tools
Low cost QuickStart development system
Full third-party support
Analog I/O
Multichannel, 12-bit, 1 MSPS ADC
Up to 14 analog-to-digital converter (ADC) channels
Fully differential and single-ended modes
0 to VREF analog input range
10-bit digital-to-analog converter (DAC)
32-bit 21 MHz direct digital synthesis (DDS)
Current-to-voltage (I/V) conversion
Integrated second-order low-pass filter (LPF)
DDS input to DAC
100 Ω line driver
On-chip voltage reference
On-chip temperature sensor (±3°C)
Voltage comparator
Microcontroller
ARM7TDMI core, 16-/32-bit RISC architecture
JTAG port supports code download and debug
External watch crystal/clock source
41.78 MHz PLL with 8-way programmable divider
Optional trimmed on-chip oscillator
Memory
126 kB Flash/EE memory, 8 kB SRAM
TEMP
SENSOR
CMP0
CMP1
CMPOUT
+
–
XCLKI
XCLKO
XCLK
DACV DD
DACGND
VDACOUT
10-BIT
IOUT DAC
DDS
I/V
I/V
LD1TX
LD2TX
LPF
BAND GAP
REFERENCE
ADuC7129
VREF
RST
LVDD
DGND
IOVDD
IOGND
IOVDD
IOGND
AVDD
12-BIT SAR
ADC 1MSPS
T/H
MUX
POR
OSC/PLL
PSM
ARM7TDMI-BASED MCU
WITH ADDITIONAL PERIPHERALS
5 GEN PURPOSE
2 kBYTES
TIMERS
62 kBYTES 64 kBYTES 8192 BYTES
WAKE-UP/
FLASH/EE FLASH/EE
SRAM
RTC TIMER
(32k ×
(31k ×
(2k ×
16 BITS)
16 BITS)
32 BITS)
INTERRUPT
CONTROLLER
GPIO
JTAG PLA SPI I2C UART0 UART1 CONTROL
JTAG
P0.0 P0.7
P1.0 P1.7
P2.0 P2.7
P3.0 P3.3
PWM
QUAD
ENCODER
PWM1
PWM2
PWM3
PWM4
PWM5
PWM6
S1
S2
06020-001
ADC0
AGND
GNDREF
FUNCTIONAL BLOCK DIAGRAM
Figure 1.
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2007 Analog Devices, Inc. All rights reserved.
ADuC7128/ADuC7129
TABLE OF CONTENTS
Features .............................................................................................. 1
Execution Time from SRAM and FLASH/EE........................ 43
Functional Block Diagram .............................................................. 1
Reset and Remap ........................................................................ 44
Revision History ............................................................................... 2
Other Analog Peripherals.............................................................. 45
General Description ......................................................................... 3
DAC.............................................................................................. 45
Specifications..................................................................................... 4
DDS .............................................................................................. 46
Timing Specifications .................................................................. 8
Power Supply Monitor ............................................................... 47
Absolute Maximum Ratings.......................................................... 15
Comparator ................................................................................. 47
ESD Caution................................................................................ 15
Oscillator and PLL—Power Control........................................ 49
Pin Configuration and Function Descriptions........................... 16
Digital Peripherals.......................................................................... 51
Typical Performance Characteristics ........................................... 21
PWM General Overview........................................................... 51
Terminology .................................................................................... 24
PWM Convert Start Control .................................................... 52
ADC Specifications .................................................................... 24
General-Purpose I/O ................................................................. 55
DAC Specifications..................................................................... 24
Serial Port Mux........................................................................... 57
Overview of the ARM7TDMI Core............................................. 25
UART Serial Interface................................................................ 57
Thumb Mode (T)........................................................................ 25
Serial Peripheral Interface......................................................... 63
Long Multiply (M)...................................................................... 25
I2C-Compatible Interfaces......................................................... 65
EmbeddedICE (I) ....................................................................... 25
I2C Registers ................................................................................ 65
Exceptions ................................................................................... 25
Programmable Logic Array (PLA)........................................... 69
ARM Registers ............................................................................ 25
Processor Reference Peripherals................................................... 72
Interrupt Latency........................................................................ 26
Interrupt System ......................................................................... 72
Memory Organization ................................................................... 27
Timers .......................................................................................... 73
Flash/EE Memory....................................................................... 27
Timer0—Lifetime Timer........................................................... 73
SRAM ........................................................................................... 27
Timer1—General-Purpose Timer ........................................... 75
Memory Mapped Registers ....................................................... 27
Timer2—Wake-Up Timer......................................................... 77
Complete MMR Listing............................................................. 28
Timer3—Watchdog Timer........................................................ 79
ADC Circuit Overview .................................................................. 32
Timer4—General-Purpose Timer ........................................... 81
ADC Transfer Function............................................................. 32
External Memory Interfacing ................................................... 83
Typical Operation....................................................................... 33
Timing Diagrams ....................................................................... 84
Converter Operation.................................................................. 36
Hardware Design Considerations ................................................ 87
Driving the Analog Inputs ........................................................ 37
Power Supplies ............................................................................ 87
Temperature Sensor ................................................................... 37
Grounding and Board Layout Recommendations................. 87
Band Gap Reference................................................................... 38
Clock Oscillator.......................................................................... 88
Nonvolatile Flash/EE Memory ..................................................... 39
Power-On Reset Operation....................................................... 89
Flash/EE Memory Overview..................................................... 39
Development Tools......................................................................... 90
Flash/EE Memory....................................................................... 39
In-Circuit Serial Downloader................................................... 90
Flash/EE Memory Security ....................................................... 40
Outline Dimensions ....................................................................... 91
Flash/EE Control Interface........................................................ 40
Ordering Guide .......................................................................... 92
REVISION HISTORY
4/07—Revision 0: Initial Version
Rev. 0 | Page 2 of 92
ADuC7128/ADuC7129
GENERAL DESCRIPTION
The ADuC7128/ADuC7129 are fully integrated, 1 MSPS, 12-bit
data acquisition systems incorporating a high performance, multichannel analog-to-digital converter (ADC), DDS with line
driver, 16-/32-bit MCU, and Flash/EE memory on a single chip.
The ADC consists of up to 14 single-ended inputs. The ADC
can operate in single-ended or differential input modes. The
ADC input voltage is 0 to VREF. Low drift band gap reference,
temperature sensor, and voltage comparator complete the ADC
peripheral set.
The ADuC7128/ADuC7129 integrate a differential line driver
output. This line driver transmits a sine wave whose values are
calculated by an on-chip DDS or a voltage output determined
by the DACDAT MMR.
The devices operate from an on-chip oscillator and PLL, generating
an internal high frequency clock of 41.78 MHz. This clock is
routed through a programmable clock divider from which the
MCU core clock operating frequency is generated.
The microcontroller core is an ARM7TDMI®, 16-/32-bit
reduced instruction set computer (RISC), offering up to
41 MIPS peak performance. There are 126 kB of nonvolatile
Flash/EE provided on-chip, as well as 8 kB of SRAM. The
ARM7TDMI core views all memory and registers as a single
linear array.
On-chip factory firmware supports in-circuit serial download
via the UART serial interface port, and nonintrusive emulation
is also supported via the JTAG interface. These features are
incorporated into a low cost QuickStart™ development system
supporting this MicroConverter® family.
The parts operate from 3.0 V to 3.6 V and are specified over an
industrial temperature range of −40°C to +125°C. When operating
at 41.78 MHz, the power dissipation is 135 mW. The line driver
output, if enabled, consumes an additional 30 mW.
Rev. 0 | Page 3 of 92
ADuC7128/ADuC7129
SPECIFICATIONS
AVDD = IOVDD = 3.0 V to 3.6 V, VREF = 2.5 V internal reference, fCORE = 41.78 MHz. All specifications TA = TMAX to TMIN, unless
otherwise noted.
Table 1.
Parameter
ADC CHANNEL SPECIFICATIONS
ADC Power-Up Time
DC Accuracy 1, 2
Resolution
Integral Nonlinearity 3
Min
Unit
Test Conditions/Comments
Eight acquisition clocks and fADC/2
μs
12
±0.7
±0.7
±2.0
±0.5
±0.6
1
DC Code Distribution
ENDPOINT ERRORS 4
Offset Error
Offset Error Match
Gain Error
Gain Error Match
DYNAMIC PERFORMANCE
Signal-to-Noise Ratio (SNR)
Total Harmonic Distortion (THD)
Peak Harmonic or Spurious Noise
Channel-to-Channel Crosstalk
Crosstalk Between Channel 12 and
Channel 13
ANALOG INPUT
Input Voltage Ranges
Differential Mode 5
Single-Ended Mode
Leakage Current
I/V Output Resistance
Low-Pass Filter 3 dB Point
Resolution
Max
5
Differential Nonlinearity3
Input Capacitance
ON-CHIP VOLTAGE REFERENCE
Output Voltage
Accuracy
Reference Drop When DAC Enabled
Reference Temperature Coefficient
Power Supply Rejection Ratio
Output Impedance
Internal VREF Power-On Time
EXTERNAL REFERENCE INPUT 6
Input Voltage Range
Input Impedance
DAC CHANNEL SPECIFICATIONS
VDAC Output
Voltage Swing
Typ
±2.0
±1.5
+1/−0.9
±5
Bits
LSB
LSB
LSB
LSB
LSB
LSB
±1
LSB
LSB
LSB
LSB
69
−78
−75
−80
−60
dB
dB
dB
dB
dB
±1
±5
2.5 V internal reference 85°C to 125°C only
2.5 V internal reference −40°C to +85°C
1.0 V external reference
2.5 V internal reference
1.0 V external reference
ADC input is a dc voltage
FIN = 10 kHz sine wave, fSAMPLE = 1 MSPS
VCM ± VREF/2
0 to VREF
±15
±3
±1
20
2.5
±2.5
9
±40
80
40
1
0.625
AVDD
38
V
V
μA
μA
pF
V
mV
mV
ppm/°C
dB
Ω
ms
85°C to 125°C only
−40°C to +85°C
During ADC acquisition
0.47 μF from VREF to AGND
Measured at TA = 25°C
Reference drop when DAC enabled
V
kΩ
RL = 5 kΩ, CL = 100 pF
VREF is the internal 2.5 V reference
(0.33 × VREF ±
0.2 × VREF) ×
1.33
7
1
10
Rev. 0 | Page 4 of 92
Ω
MHz
Bits
V mode selected
2-pole at 1.5 MHz and 2 MHz
ADuC7128/ADuC7129
Parameter
Relative Accuracy
Differential Nonlinearity, +VE
Differential Nonlinearity, −VE
Offset Error
Gain Error
Voltage Output Settling Time
to 0.1%
Line Driver Output
Min
DC Mode
11
dB
V rms
1.65
V
1.5
V
13
±50
20
±15
1
AGND
15
Input Capacitance
pF
mV
1
μs
780
−1.3
±3
mV
mV/°C
°C
2.79
3.07
±2.5
50
V
V
%
μs
0
512
FLASH/EE MEMORY 7, 8
Endurance
Data Retention
DIGITAL INPUTS
Logic 1 Input Current (Leakage
Current)
Logic 0 Input Current (Leakage
Current)
As measured into a range of specified loads
(see Figure 2) at LD1TX and LD2TX, unless
otherwise noted
PLM operating at 691.2 kHz
Each output has a common mode of 0.5 V × AVDD
and swings 0.5 V × VREF above and below this;
VREF is the internal 2.5 V reference
Each output has a common mode of 0.5 V × VREF
and swings 0.6 V × VREF above and below this;
VREF is the internal 2.5 V reference
Line driver buffer disabled
Line driver buffer disabled
No protection diodes, max allowable current
AVDD − 1.2 V
2
Power Supply Trip Point Accuracy
GLITCH IMMUNITY ON RST PIN3
kΩ
μA
mA
μs
Test Conditions/Comments
mV
μA
7
TEMPERATURE SENSOR
Voltage Output at 25°C
Voltage Temperature Coefficient
Accuracy
POWER SUPPLY MONITOR (PSM)
IOVDD Trip Point Selection
Unit
LSB
LSB
LSB
mV
mV
μs
−52
±1.768
7
Response Time
WATCHDOG TIMER (WDT)
Timeout Period
Max
−190
+150
5
Total Harmonic Distortion
Output Voltage Swing
COMMON MODE
AC Mode
DIFFERENTIAL INPUT IMPEDANCE
Leakage Current LD1TX, LD2TX
Short-Circuit Current
Line Driver Tx Power-Up Time
COMPARATOR
Input Offset Voltage
Input Bias Current
Input Voltage Range
Input Capacitance
Hysteresis3, 5
Typ
±2
0.35
−0.15
10,000
20
Hysteresis can be turned on or off via the
CMPHYST bit in the CMPCON register
Response time can be modified via the CMPRES
bits in the CMPCON register
Two selectable trip points
Of the selected nominal trip point voltage
ms
sec
Cycles
Years
±0.2
±1
μA
TJ = 85°C
All digital inputs, including XCLKI and XCLKO
VINH = VDD or VINH = 5 V
−40
−65
μA
VINL = 0 V, except TDI
−80
15
+125
μA
pF
VINL = 0 V, TDI Only
Rev. 0 | Page 5 of 92
ADuC7128/ADuC7129
Parameter
LOGIC INPUTS3
VINL, Input Low Voltage
VINH, Input High Voltage
Quadrature Encoder Inputs
S1/S2/CLR (Schmitt-Triggered Inputs)
VT+
VT−
VT+ − VT−
LOGIC OUTPUTS 9
VOH, Output High Voltage
Min
Typ
Max
Unit
0.8
V
V
2.0
1.65
1.2
0.75
V
V
V
IOVDD −
400 mV
VOL, Output Low Voltage
CRYSTAL INPUTS XCLKI and XCLKO
VINL, Input Low Voltage
VINH, Input High Voltage
XCLKI, Input Capacitance
XCLKO, Output Capacitance
MCU CLOCK RATE (PLL)
0.4
1.1
1.7
20
20
326.4
41.77920
INTERNAL OSCILLATOR
Tolerance
STARTUP TIME
At Power-On
From Sleep Mode
From Stop Mode
PROGRAMMABLE LOGIC ARRAY (PLA)
Pin Propagation Delay
Element Propagation Delay
POWER REQUIREMENTS
Power Supply Voltage Range
IOVDD, AVDD, and DACVDD (Supply
Voltage to Chip)
LVDD (Regulator Output from Chip)
Power Supply Current 10, 11
Normal Mode
Additional Line Driver Tx Supply
Current
Pause Mode
Sleep Mode
32.768
±3
±4
2.5
V
ISOURCE = 1.6 mA
V
ISINK = 1.6 mA
V
V
pF
pF
Logic inputs, XCLKI only
Logic inputs, XCLKI only
kHz
MHz
kHz
%
%
70
1.6
1.6
ms
ms
ms
12
2.5
ns
ns
3.0
Test Conditions/Comments
All logic inputs, including XCLKI and XCLKO
Eight programmable core clock selections
within this range
(32.768 kHz x 1275)/128
(32.768 kHz x 1275)/1
−40°C to 85°C
85°C to 125°C only
Core clock = 41.78 MHz
From input pin to output pin
3.6
V
2.6
2.7
V
15
19
mA
5.22 MHz clock
42
49
30
mA
mA
41.78 MHz clock
691 kHz, maximum load (see Figure 2)
37
3.6
mA
mA
41.78 MHz clock
External crystal or internal OSC ON
0.3
1
All ADC channel specifications are guaranteed during normal MicroConverter core operation.
Apply to all ADC input channels.
3
Not production tested; supported by design and/or characterization of data on production release.
4
Measured using an external AD845 op amp as an input buffer stage, as shown in Figure 42. Based on external ADC system components.
5
The input signal can be centered on any dc common-mode voltage (VCM), as long as this value is within the ADC voltage input range specified.
6
When using an external reference input pin, the internal reference must be disabled by setting the LSB in the REFCON memory mapped register to 0.
7
Endurance is qualified as per JEDEC Std. 22 Method A117 and measured at −40°C, +25°C, and +85°C.
8
Retention lifetime equivalent at junction temperature (TJ) = 85°C as per JEDEC Std. 22 Method A117. Retention lifetime derates with junction temperature.
9
Test carried out with a maximum of eight I/Os set to a low output level.
10
Power supply current consumption is measured in normal, pause, and sleep modes under the following conditions: normal mode = 3.6 V supply, pause mode = 3.6 V
supply, sleep mode = 3.6 V supply.
11
IOVDD power supply current decreases typically by 2 mA during a Flash/EE erase cycle.
2
Rev. 0 | Page 6 of 92
ADuC7128/ADuC7129
Line Driver Load
94Ω
100nF
94Ω
100nF
94Ω
100nF
94Ω
118Ω
LD2TX
LD1TX
57Ω
LD2TX
27.5µH
8.9µH
06020-002
100nF
LD1TX
Figure 2. Line Driver Load Minimum (Top) and Maximum (Bottom)
Rev. 0 | Page 7 of 92
ADuC7128/ADuC7129
TIMING SPECIFICATIONS
Table 2. External Memory Write Cycle
Parameter
CLK
tMS_AFTER_CLKH
tADDR_AFTER_CLKH
tAE_H_AFTER_MS
tAE
tHOLD_ADDR_AFTER_AE_L
tHOLD_ADDR_BEFORE_WR_L
tWR_L_AFTER_AE_L
tDATA_AFTER_WR_L
tWR
tWR_H_AFTER_CLKH
tHOLD_DATA_AFTER_WR_H
tBEN_AFTER_AE_L
tRELEASE_MS_AFTER_WR_H
Min
Typ
UCLK
0
4
Max
Unit
4
8
ns
ns
12
ns
4
ns
½ CLK
(XMxPAR[14:12] + 1) × CLK
½ CLK + (!XMxPAR[10]) × CLK
(!XMxPAR[8]) × CLK
½ CLK + (!XMxPAR[10] + !XMxPAR[8]) × CLK
8
(XMxPAR[7:4] + 1) × CLK
0
(!XMxPAR[8]) × CLK
½ CLK
(!XMxPAR[8] + 1) × CLK
CLK
CLK
tMS_AFTER_CLKH
MS
tWR_L_AFTER_AE_L
tAE_H_AFTER_MS
AE
tWR
tRELEASE_MS_AFTER_WR_H
tAE
tWR_H_AFTER_CLKH
WS
tHOLD_DATA_AFTER_WR_H
RS
tHOLD_ADDR_AFTER_AE_L
tHOLD_ADDR_BEFORE_WR_L
tADDR_AFTER_CLKH
A/D[15:0]
FFFF
9ABC
tDATA_AFTER_WR_L
5678
9ABE
1234
tBEN_AFTER_AE_L
BLE
06020-065
BHE
A16
Figure 3. External Memory Write Cycle
Rev. 0 | Page 8 of 92
ADuC7128/ADuC7129
Table 3. External Memory Read Cycle
Parameter
CLK
tMS_AFTER_CLKH
tADDR_AFTER_CLKH
tAE_H_AFTER_MS
tAE
tHOLD_ADDR_AFTER_AE_L
tRD_L_AFTER_AE_L
tRD_H_AFTER_CLKH
tRD
tDATA_BEFORE_RD_H
tDATA_AFTER_RD_H
tRELEASE_WS_AFTER_RD_H
Min
1/MD Clock
4
4
Typ
ns typ × (CDPOWCON[2:0] + 1)
Max
Unit
8
16
ns
ns
4
ns
½ CLK
(XMxPAR[14:12] + 1) × CLK
½ CLK + (! XMxPAR[10] ) × CLK
½ CLK + (! XMxPAR[10]+ ! XMxPAR[9] ) × CLK
0
(XMxPAR[3:0] + 1) × CLK
16
8
0ns
50ns
ns
+ (! XMxPAR[9]) × CLK
1 × CLK
100ns
150ns
200ns
250ns
300ns
350ns
400ns
CLK
ECLK
tMS_AFTER_CLKH
GP0
tAE_H_AFTER_MS
tAE
tRELEASE_WS_AFTER_RD_H
tRD_L_AFTER_AE_L
AE
WS
tRD
tRD_H_AFTER_CLKH
RS
SAMPLE_ADDR_1
tDATA_BEFORE_RD_H
tADDR_AFTER_CLKH
tDATA_AFTER_RD_H
SAMPLE_ADDR_0
A/D[15:0]
FFFF
2348
XXXX
CDEF XX
234A
SAMPLE_DATA_L
XX
89AB
SAMPLE_DATA_H
tHOLD_ADDR_AFTER_AE_L
BLE
06020-067
BHE
XA16
Figure 4. External Memory Read Cycle
Rev. 0 | Page 9 of 92
ADuC7128/ADuC7129
I2C® Timing Specifications
Table 4. I2C Timing in Fast Mode (400 kHz)
P
P
Parameter
tL
tH
tSHD
tDSU
tDHD
tRSU
tPSU
tBUF
tR
tF
tSUP
Slave Min
200
100
300
100
0
100
100
1.3
100
60
Slave Max
Master Typ
1360
1140
251,350
740
400
12.51350
400
300
300
50
200
20
Unit
ns
ns
ns
ns
ns
ns
ns
μs
ns
ns
ns
tHCLK depends on the clock divider or CD bits in the PLLCON MMR, tHCLK = tUCLK/2CD.
tBUF
tSUP
tR
SDATA (I/O)
MSB
LSB
tDSU
tSHD
tF
tDHD
2–7
8
tL
PS
tR
tRSU
tH
1
SCLOCK (I)
MSB
tDSU
tDHD
tPSU
ACK
9
tSUP
STOP
START
CONDITION CONDITION
1
S(R)
REPEATED
START
Figure 5. I2C-Compatible Interface Timing
P
P
Rev. 0 | Page 10 of 92
tF
06020-003
1
Description
SCLOCK low pulse width1
SCLOCK high pulse width1
Start condition hold time
Data setup time
Data hold time
Setup time for repeated start
Stop condition setup time
Bus-free time between a stop condition and a start condition
Rise time for both SCLOCK and SDATA
Fall time for both SCLOCK and SDATA
Pulse width of spike suppressed
ADuC7128/ADuC7129
SPI Timing Specifications
Table 5. SPI Master Mode Timing (PHASE Mode = 1)
Parameter
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
2
Min
Typ
(SPIDIV + 1) × tHCLK
(SPIDIV + 1) × tHCLK
Max
2 × tHCLK + 2 × tUCLK
1 × tUCLK
2 × tUCLK
5
5
5
5
12.5
12.5
12.5
12.5
tHCLK depends on the clock divider or CD bits in the PLLCON MMR, tHCLK = tUCLK/2CD.
tUCLK = 23.9 ns. It corresponds to the 41.78 MHz internal clock from the PLL before the clock divider.
SCLOCK
(POLARITY = 0)
tSH
tSL
tSR
SCLOCK
(POLARITY = 1)
tDAV
tDF
MOSI
MISO
MSB
MSB IN
tSF
tDR
BIT 6 TO BIT 1
BIT 6 TO BIT 1
tDSU
LSB
LSB IN
06020-004
1
Description
SCLOCK low pulse width 1
SCLOCK high pulse width1
Data output valid after SCLOCK edge
Data input setup time before SCLOCK edge 2
Data input hold time after SCLOCK edge2
Data output fall time
Data output rise time
SCLOCK rise time
SCLOCK fall time
tDHD
Figure 6. SPI Master Mode Timing (PHASE Mode = 1)
Rev. 0 | Page 11 of 92
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ADuC7128/ADuC7129
Table 6. SPI Master Mode Timing (PHASE Mode = 0)
Parameter
tSL
tSH
tDAV
tDOSU
tDSU
tDHD
tDF
tDR
tSR
tSF
2
Min
Typ
(SPIDIV + 1) × tHCLK
(SPIDIV + 1) × tHCLK
Max
2 × tHCLK + 2 × tUCLK
75
1 × tUCLK
2 × tUCLK
5
5
5
5
12.5
12.5
12.5
12.5
tHCLK depends on the clock divider or CD bits in the PLLCON MMR, tHCLK = tUCLK/2CD.
tUCLK = 23.9 ns. It corresponds to the 41.78 MHz internal clock from the PLL before the clock divider.
SCLOCK
(POLARITY = 0)
tSH
tSL
tSR
tSF
SCLOCK
(POLARITY = 1)
tDAV
tDOSU
MOSI
MISO
tDF
MSB
tDR
BIT 6 TO BIT 1
MSB IN
BIT 6 TO BIT 1
LSB
LSB IN
tDSU
06020-005
1
Description
SCLOCK low pulse width 1
SCLOCK high pulse width1
Data output valid after SCLOCK edge
Data output setup before SCLOCK edge
Data input setup time before SCLOCK edge 2
Data input hold time after SCLOCK edge2
Data output fall time
Data output rise time
SCLOCK rise time
SCLOCK fall time
tDHD
Figure 7. SPI Master Mode Timing (PHASE Mode = 0)
Rev. 0 | Page 12 of 92
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ADuC7128/ADuC7129
Table 7. SPI Slave Mode Timing (PHASE Mode = 1)
Parameter
tCS
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
tSFS
2
Min
2 × tUCLK
Typ
Max
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
(SPIDIV + 1) × tHCLK
(SPIDIV + 1) × tHCLK
2 × tHCLK + 2 × tUCLK
1 × tUCLK
2 × tUCLK
5
5
5
5
12.5
12.5
12.5
12.5
0
tUCLK = 23.9 ns. It corresponds to the 41.78 MHz internal clock from the PLL before the clock divider.
tHCLK depends on the clock divider or CD bits in the PLLCON MMR, tHCLK = tUCLK/2CD.
CS
tSFS
tCS
SCLOCK
(POLARITY = 0)
tSH
tSL
tSR
tSF
SCLOCK
(POLARITY = 1)
tDAV
MISO
tDF
MSB
MOSI
MSB IN
tDR
BIT 6 TO BIT 1
BIT 6 TO BIT 1
LSB
LSB IN
tDSU
06020-006
1
Description
CS to SCLOCK edge 1
SCLOCK low pulse width 2
SCLOCK high pulse width2
Data output valid after SCLOCK edge
Data input setup time before SCLOCK edge1
Data input hold time after SCLOCK edge1
Data output fall time
Data output rise time
SCLOCK rise time
SCLOCK fall time
CS high after SCLOCK edge
tDHD
Figure 8. SPI Slave Mode Timing (PHASE Mode = 1)
Rev. 0 | Page 13 of 92
ADuC7128/ADuC7129
Table 8. SPI Slave Mode Timing (PHASE Mode = 0)
Parameter
tCS
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
tDOCS
tSFS
2
Min
2 × tUCLK
Typ
Max
(SPIDIV + 1) × tHCLK
(SPIDIV + 1) × tHCLK
2 × tHCLK + 2 × tUCLK
1 × tUCLK
2 × tUCLK
5
5
5
5
12.5
12.5
12.5
12.5
25
0
tUCLK = 23.9 ns. It corresponds to the 41.78 MHz internal clock from the PLL before the clock divider.
tHCLK depends on the clock divider or CD bits in the PLLCON MMR, tHCLK = tUCLK/2CD.
CS
tCS
tSFS
SCLOCK
(POLARITY = 0)
tSH
tSL
tSF
tSR
SCLOCK
(POLARITY = 1)
tDAV
tDOCS
tDF
MISO
MOSI
MSB
MSB IN
tDSU
tDR
BIT 6 TO BIT 1
BIT 6 TO BIT 1
LSB
LSB IN
06020-007
1
Description
CS to SCLOCK edge 1
SCLOCK low pulse width 2
SCLOCK high pulse width2
Data output valid after SCLOCK edge
Data input setup time before SCLOCK edge1
Data input hold time after SCLOCK edge1
Data output fall time
Data output rise time
SCLOCK rise time
SCLOCK fall time
Data output valid after CS edge
CS high after SCLOCK edge
tDHD
Figure 9. SPI Slave Mode Timing (PHASE Mode = 0)
Rev. 0 | Page 14 of 92
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ADuC7128/ADuC7129
ABSOLUTE MAXIMUM RATINGS
DVDD = IOVDD, AGND = REFGND = DACGND = GNDREF.
TA = 25°C, unless otherwise noted.
Table 9.
Parameter
AVDD to DVDD
AGND to DGND
IOVDD to IOGND, AVDD to AGND
Digital Input Voltage to IOGND
Digital Output Voltage to IOGND
VREF to AGND
Analog Inputs to AGND
Analog Output to AGND
Operating Temperature Range
Industrial
Storage Temperature Range
Junction Temperature
θJA Thermal Impedance
64-Lead LFCSP
64-Lead LQFP
80-Lead LQFP
Peak Solder Reflow Temperature
SnPb Assemblies (10 sec to 30 sec)
RoHS Compliant Assemblies
(20 sec to 40 sec)
Rating
−0.3 V to +0.3 V
−0.3 V to +0.3 V
−0.3 V to +6 V
−0.3 V to IOVDD + 0.3 V
−0.3 V to IOVDD + 0.3 V
−0.3 V to AVDD + 0.3 V
−0.3 V to AVDD + 0.3 V
−0.3 V to AVDD + 0.3 V
–40°C to +125°C
–65°C to +150°C
150°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Only one absolute maximum rating can be applied at any one
time.
ESD CAUTION
24°C/W
47°C/W
38°C/W
240°C
260°C
Rev. 0 | Page 15 of 92
ADuC7128/ADuC7129
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
ADC4
ADC3/CMP1
ADC2/CMP0
ADC1
ADC0
DACV DD
AVDD
AGND
DACGND
VREF
P4.5
P4.4
P4.3/PWMTRIP
P4.2
P1.0/SPM0
P1.1/SPM1
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
PIN 1
INDICATOR
ADuC7128
TOP VIEW
(Not to Scale)
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P1.2/SPM2
P1.3/SPM3
P1.4/SPM4
P1.5/SPM5
P4.1/S2
P4.0/S1
IOVDD
IOGND
P1.6/SPM6
P1.7/SPM7
DGND
PVDD
XCLKI
XCLKO
P0.7/SPM8/ECLK/XCLK
P2.0/SPM9
06020-063
TCK
TDO
IOGND
IOVDD
LVDD
DGND
P3.0/PWM1
P3.1/PWM2
P3.2/PWM3
P3.3/PWM4
P0.3/ADCBUSY /TRST
RST
P3.4/PWM5
P3.5/PWM6
P0.4/IRQ0/CONVST
P0.5/IRQ1/ADCBUSY
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
ADC5
VDACOUT
ADC9
ADC10
GNDREF
ADCNEG
AVDD
ADC12/LD1TX
ADC13/LD2TX
AGND
TMS
TDI
P4.6/SPM10
P4.7/SPM11
P0.0/BM/CMPOUT
P0.6/T1/MRST
Figure 10. ADuC7128 Pin Configuration
Table 10. ADuC7128 Pin Function Descriptions
Pin
No.
1
2
3
4
5
Mnemonic
ADC5
VDACOUT
ADC9
ADC10
GNDREF
Type 1
I
O
I
I
S
6
ADCNEG
I
7, 58
8
9
10, 57
11
12
13
14
15
AVDD
ADC12/LD1TX
ADC13/LD2TX
AGND
TMS
TDI
P4.6/SPM10
P4.7/SPM11
P0.0/BM/CMPOUT
S
I/O
I/O
S
I
I
I/O
I/O
I/O
16
17
18
19, 41
20, 42
P0.6/T1/MRST
TCK
TDO
IOGND
IOVDD
O
I
O
S
S
Description
Single-Ended or Differential Analog Input 5/Line Driver Input.
Output from DAC Buffer.
Single-Ended or Differential Analog Input 9.
Single-Ended or Differential Analog Input 10.
Ground Voltage Reference for the ADC. For optimal performance, the analog power supply
should be separated from IOGND and DGND.
Bias Point or Negative Analog Input of the ADC in Pseudo Differential Mode. Must be
connected to the ground of the signal to convert. This bias point must be between
0 V and 1 V.
Analog Power.
Single-Ended or Differential Analog Input 12/DAC Differential Negative Output.
Single-Ended or Differential Analog Input 13/DAC Differential Positive Output.
Analog Ground. Ground reference point for the analog circuitry.
JTAG Test Port Input, Test Mode Select. Debug and download access.
JTAG Test Port Input, Test Data In. Debug and download access.
General-Purpose Input and Output Port 4.6/Serial Port Mux Pin 10.
General-Purpose Input and Output Port 4.7/Serial Port Mux Pin 11.
General-Purpose Input and Output Port 0.0/Boot Mode. The ADuC7128 enters download
mode if BM is low at reset and executes code if BM is pulled high at reset through a 1 kΩ
resistor/voltage comparator output.
General-Purpose Output Port 0.6/Timer1 Input/Power-On Reset Output.
JTAG Test Port Input, Test Clock. Debug and download access.
JTAG Test Port Output, Test Data Out. Debug and download access.
Ground for GPIO. Typically connected to DGND.
3.3 V Supply for GPIO and Input of the On-Chip Voltage Regulator.
Rev. 0 | Page 16 of 92
ADuC7128/ADuC7129
Pin
No.
21
Mnemonic
LVDD
Type 1
S
22
23
24
25
26
27
DGND
P3.0/PWM1
P3.1/PWM2
P3.2/PWM3
P3.3/PWM4
P0.3/ADCBUSY/TRST
S
I/O
I/O
I/O
I/O
I/O
28
29
30
31
RST
P3.4/PWM5
P3.5/PWM6
P0.4/IRQ0/CONVST
I
I/O
I/O
I/O
32
P0.5/IRQ1/ADCBUSY
I/O
33
34
P2.0/SPM9
P0.7/SPM8/ECLK/XCLK
I/O
I/O
35
36
37
XCLKO
XCLKI
PVDD
O
I
S
38
39
40
43
44
45
46
47
48
49
50
51
52
53
54
55
DGND
P1.7/SPM7
P1.6/SPM6
P4.0/S1
P4.1/S2
P1.5/SPM5
P1.4/SPM4
P1.3/SPM3
P1.2/SPM2
P1.1/SPM1
P1.0/SPM0
P4.2
P4.3/ PWMTRIP
P4.4
P4.5
VREF
S
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
56
59
DACGND
DACVDD
S
S
60
61
62
63
64
ADC0
ADC1
ADC2/CMP0
ADC3/CMP1
ADC4
I
I
I
I
I
1
Description
2.5 V Output of the On-Chip Voltage Regulator. Must be connected to a 0.47 μF capacitor
to DGND.
Ground for Core Logic.
General-Purpose Input and Output Port 3.0/PWM1 Output.
General-Purpose Input and Output Port 3.1/PWM2 Output.
General-Purpose Input and Output Port 3.2/PWM3 Output.
General-Purpose Input and Output Port 3.3/PWM4 Output.
General-Purpose Input and Output Port 3.3/ADCBUSY Signal/JTAG Test Port Input, Test Reset.
Debug and download access.
Reset Input (Active Low).
General-Purpose Input and Output Port 3.4/PWM5 Output.
General-Purpose Input and Output Port 3.5/PWM6 Output.
General-Purpose Input and Output Port 0.5/External Interrupt Request 0, Active High/Start
Conversion Input Signal for ADC.
General-Purpose Input and Output Port 0.6/External Interrupt Request 1, Active High/ADCBUSY
Signal.
General-Purpose Input and Output Port 2.0/Serial Port Mux Pin 9.
General-Purpose Input and Output Port 0.7/Serial Port Mux Pin 8/Output for the External
Clock Signal/Input to the Internal Clock Generator Circuits.
Output from the Crystal Oscillator Inverter.
Input to the Crystal Oscillator Inverter and Input to the Internal Clock Generator Circuits.
2.5 V PLL Supply. Must be connected to a 0.1 μF capacitor to DGND. Should be connected to
2.5 V LDO output.
Ground for PLL.
General-Purpose Input and Output Port 1.7/Serial Port Mux Pin 7.
General-Purpose Input and Output Port 1.6/Serial Port Mux Pin 6.
General-Purpose Input and Output Port 4.0/Quadrature Input 1.
General-Purpose Input and Output Port 4.1/Quadrature Input 2.
General-Purpose Input and Output Port 1.5/Serial Port Mux Pin 5.
General-Purpose Input and Output Port 1.4/Serial Port Mux Pin 4.
General-Purpose Input and Output Port 1.3/Serial Port Mux Pin 3.
General-Purpose Input and Output Port 1.2/Serial Port Mux Pin 2.
General-Purpose Input and Output Port 1.1/Serial Port Mux Pin 1.
General-Purpose Input and Output Port 1.0/Serial Port Mux Pin 0.
General-Purpose Input and Output Port 4.2.
General-Purpose Input and Output Port 4.3/PWM Safety Cutoff.
General-Purpose Input and Output Port 4.4.
General-Purpose Input and Output Port 4.5.
2.5 V Internal Voltage Reference. Must be connected to a 0.47 μF capacitor when using the
internal reference.
Ground for the DAC. Typically connected to AGND.
Power Supply for the DAC. This must be supplied with 2.5 V. This can be connected to the LDO
output.
Single-Ended or Differential Analog Input 0.
Single-Ended or Differential Analog Input 1.
Single-Ended or Differential Analog Input 2/Comparator Positive Input.
Single-Ended or Differential Analog Input 3/Comparator Negative Input.
Single-Ended or Differential Analog Input 4.
I = input, O = output, S = supply.
Rev. 0 | Page 17 of 92
P1.1/SPM1
P1.0/SPM0
P4.2/AD10
P4.3/PWMTRIP/AD11
P4.4/AD12
P4.5/AD13
IOGND
REFGND
VREF
DACGND
AGND
AGND
AVDD
AVDD
DACV DD
ADC11
ADC0
ADC1
ADC2/CMP0
ADC3/CMP1
ADuC7128/ADuC7129
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
60
P1.2/SPM2
59
P1.3/SPM3
3
58
P1.4/SPM4
4
57
P1.5/SPM5
VDACOUT/ADC8 5
56
P4.1/S2/AD9
ADC4 1
ADC5
2
ADC6
ADC7
PIN 1
ADC9
6
55
P4.0/S1/AD8
ADC10
7
54
IOVDD
GNDREF
8
53
IOGND
ADCNEG
9
ADuC7129
52
P1.6/SPM6
AVDD 10
TOP VIEW
(Not to Scale)
51
P1.7/SPM7
50
P2.2/RS
ADC13/LD2TX 12
49
P2.1/WS
AGND 13
48
P2.7/MS3
TMS 14
47
P3.7/AD7
TDI/P0.1/BLE 15
46
P3.6/AD6
P2.3/AE 16
45
DGND
P4.6/SPM10/AD14 17
44
PVDD
P4.7/SPM11/AD15 18
43
XCLKI
P0.0/BM/CMPOUT/MS0 19
42
XCLKO
P0.6/T1/MRST 20
41
P0.7/SPM8/ECLK/XCLK
ADC12/LD1TX 11
06020-064
P2.0/SPM9
P0.5/IRQ1/ADCBUSY
P0.4/IRQ0/CONVST/MS1
P3.5/PWM6/AD5
P3.4/PWM5/AD4
RST
P2.6/MS2
P2.5/MS1
P0.3/ADC BUSY /TRST/A16
P2.4/MS0
P3.3/PWM4/AD3
P3.2/PWM3/AD2
P3.1/PWM2/AD1
P3.0/PWM1/AD0
DGND
LVDD
IOVDD
IOGND
TCK
TDO/P0.2/BHE
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
Figure 11. ADuC7129 Pin Configuration
Table 11. ADuC7129 Pin Function Descriptions
Pin
No.
1
2
3
4
5
6
7
8
Mnemonic
ADC4
ADC5
ADC6
ADC7
VDACOUT/ADC8
ADC9
ADC10
GNDREF
Type1
I
I
I
I
I
I
I
S
9
ADCNEG
I
10, 73, 74
11
12
13
14
15
AVDD
ADC12/LD1TX
ADC13/LD2TX
AGND
TMS
TDI/P0.1/BLE
S
I/O
I/O
S
I
I/0
16
P2.3/AE
I/O
Description
Single-Ended or Differential Analog Input 4.
Single-Ended or Differential Analog Input 5.
Single-Ended or Differential Analog Input 6.
Single-Ended or Differential Analog Input 7.
Output from DAC Buffer/Single-Ended or Differential Analog Input 8.
Single-Ended or Differential Analog Input 9.
Single-Ended or Differential Analog Input 10.
Ground Voltage Reference for the ADC. For optimal performance, the analog power supply
should be separated from IOGND and DGND.
Bias Point or Negative Analog Input of the ADC in Pseudo Differential Mode. Must be
connected to the ground of the signal to convert. This bias point must be between
0 V and 1 V.
3.3 V Analog Supply.
Single-Ended or Differential Analog Input 12/DAC Differential Negative Output.
Single-Ended or Differential Analog Input 13/DAC Differential Positive Output.
Analog Ground. Ground reference point for the analog circuitry.
JTAG Test Port Input, Test Mode Select. Debug and download access.
JTAG Test Port Input, Test Data In. Debug and download access/general-purpose input and
output Port 0.1/External Memory BLE.
General-Purpose Input and Output Port 2.3/AE Output.
Rev. 0 | Page 18 of 92
ADuC7128/ADuC7129
Pin
No.
17
18
19
Mnemonic
P4.6/SPM10/AD14
P4.7/SPM11/AD15
P0.0/BM/CMPOUT/MS0
Type1
I/O
I/O
I/O
20
21
22
P0.6/T1/MRST
TCK
TDO/P0.2/BHE
O
I
O
23, 53, 67
24, 54
25
IOGND
IOVDD
LVDD
S
S
S
26
27
28
29
30
31
32
DGND
P3.0/PWM1/AD0
P3.1/PWM2/AD1
P3.2/PWM3/AD2
P3.3/PWM4/AD3
P2.4/MS0
P0.3/ADCBUSY/TRST/A16
S
I/O
I/O
I/O
I/O
I/O
I/O
33
34
35
36
37
38
P2.5/MS1
P2.6/MS2
RST
P3.4/PWM5/AD4
P3.5/PWM6/AD5
P0.4/IRQ0/CONVST/MS1
I/O
I/O
I
I/O
I/O
I/O
39
P0.5/IRQ1/ADCBUSY
I/O
40
41
P2.0/SPM9
P0.7/SPM8/ECLK/XCLK
I/O
I/O
42
43
44
XCLKO
XCLKI
PVDD
O
I
S
45
46
47
48
49
50
51
52
55
56
57
58
59
60
61
62
DGND
P3.6/AD6
P3.7/AD7
P2.7/MS3
P2.1/WS
P2.2/RS
P1.7/SPM7
P1.6/SPM6
P4.0/S1/AD8
P4.1/S2/AD9
P1.5/SPM5
P1.4/SPM4
P1.3/SPM3
P1.2/SPM2
P1.1/SPM1
P1.0/SPM0
S
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
Description
General-Purpose Input and Output Port 4.6/Serial Port Mux Pin 10/External Memory AD14.
General-Purpose Input and Output Port 4.7/Serial Port Mux Pin 11/External Memory AD15.
General-Purpose Input and Output Port 0.0 /Boot Mode. The ADuC7129 enters download
mode if BM is low at reset and executes code if BM is pulled high at reset through a 1 kΩ
resistor/voltage comparator output/external memory MS0.
General-Purpose Output Port 0.6/Timer1 Input/Power-On Reset Output/External Memory AE.
JTAG Test Port Input, Test Clock. Debug and download access.
JTAG Test Port Output, Test Data Out. Debug and download access/general-purpose input
and output Port 0.2/External Memory BHE.
Ground for GPIO. Typically connected to DGND.
3.3 V Supply for GPIO and Input of the On-Chip Voltage Regulator.
2.5 V Output of the On-Chip Voltage Regulator. Must be connected to a 0.47 μF capacitor
to DGND.
Ground for Core Logic.
General-Purpose Input and Output Port 3.0/PWM1 Output/External Memory AD0.
General-Purpose Input and Output Port 3.1/PWM2 Output/External Memory AD1.
General-Purpose Input and Output Port 3.2/PWM3 Output/External Memory AD2.
General-Purpose Input and Output Port 3.3/PWM4 Output//External Memory AD3.
General-Purpose Input and Output Port 2.4/Memory Select 0.
General-Purpose Input and Output Port 3.3/ADCBUSY Signal/JTAG Test Port Input, Test Reset.
Debug and download access/External Memory A16.
General-Purpose Input and Output Port 2.5/Memory Select 1.
General-Purpose Input and Output Port 2.6/Memory Select 2.
Reset Input (Active Low).
General-Purpose Input and Output Port 3.4/PWM5 Output/External Memory AD4.
General-Purpose Input and Output Port 3.5/PWM6 Output/External Memory AD5.
General-Purpose Input and Output Port 0.5/External Interrupt Request 0, Active High/Start
Conversion Input Signal for ADC/External Memory MS1.
General-Purpose Input and Output Port 0.6/External Interrupt Request 1, Active
High/ADCBUSY Signal.
General-Purpose Input and Output Port 2.0/Serial Port Mux Pin 9.
General-Purpose Input and Output Port 0.7/Serial Port Mux Pin 8/Output for the External
Clock Signal/Input to the Internal Clock Generator Circuits.
Output from the Crystal Oscillator Inverter.
Input to the Crystal Oscillator Inverter and Input to the Internal Clock Generator Circuits.
2.5 V PLL Supply. Must be connected to a 0.1 μF capacitor to DGND. Should be connected
to 2.5 V LDO output.
Ground for PLL.
General-Purpose Input and Output Port 3.6/External Memory AD6.
General-Purpose Input and Output Port 3.7/External Memory AD7.
General-Purpose Input and Output Port 2.7/Memory Select 3.
General-Purpose Input and Output Port 2.1/Memory Write Select.
General-Purpose Input and Output Port 2.1/Memory Read Select.
General-Purpose Input and Output Port 1.7/Serial Port Mux Pin 7.
General-Purpose Input and Output Port 1.6/Serial Port Mux Pin 6.
General-Purpose Input and Output Port 4.0/Quadrature Input 1/External Memory AD8.
General-Purpose Input and Output Port 4.1/Quadrature Input 2/External Memory AD9.
General-Purpose Input and Output Port 1.5/Serial Port Mux Pin 5.
General-Purpose Input and Output Port 1.4/Serial Port Mux Pin 4.
General-Purpose Input and Output Port 1.3/Serial Port Mux Pin 3.
General-Purpose Input and Output Port 1.2/Serial Port Mux Pin 2.
General-Purpose Input and Output Port 1.1/Serial Port Mux Pin 1.
General-Purpose Input and Output Port 1.0/Serial Port Mux Pin 0.
Rev. 0 | Page 19 of 92
ADuC7128/ADuC7129
Pin
No.
63
64
65
66
68
69
Mnemonic
P4.2/AD10
P4.3/PWMTRIP/AD11
P4.4/AD12
P4.5/AD13
REFGND
VREF
Type1
I/O
I/O
I/O
I/O
S
I/O
70
71, 72
75
DACGND
AGND
DACVDD
S
S
S
76
77
78
79
80
ADC11
ADC0
ADC1
ADC2/CMP0
ADC3/CMP1
I
I
I
I
I
1
Description
General-Purpose Input and Output Port 4.2/External Memory AD10.
General-Purpose Input and Output Port 4.3/PWM Safety Cutoff/External Memory AD11.
General-Purpose Input and Output Port 4.4/External Memory AD12.
General-Purpose Input and Output Port 4.5/External Memory AD13.
Ground for VREF. Typically connected to DGND.
2.5 V Internal Voltage Reference. Must be connected to a 0.47 μF capacitor when using the
internal reference.
Ground for the DAC. Typically connected to AGND.
Analog Ground.
Power Supply for the DAC. This must be supplied with 2.5 V. It can be connected to the LDO
output.
Single-Ended or Differential Analog Input 11.
Single-Ended or Differential Analog Input 0.
Single-Ended or Differential Analog Input 1.
Single-Ended or Differential Analog Input 2/Comparator Positive Input.
Single-Ended or Differential Analog Input 3/Comparator Negative Input.
I = input, O = output, S = supply.
Rev. 0 | Page 20 of 92
ADuC7128/ADuC7129
TYPICAL PERFORMANCE CHARACTERISTICS
1.0
fS = 774kSPS
0.4
0.2
0.2
(LSB)
0.6
0.4
(LSB)
0.6
0
0
–0.2
–0.2
–0.4
–0.4
–0.6
–0.6
–0.8
–0.8
0
1000
2000
ADC CODES
3000
4000
–1.0
06020-008
–1.0
fS = 774kSPS
0.8
0
Figure 12. Typical INL Error, fS = 774 kSPS
1.0
1.0
0.4
0.2
0.2
(LSB)
0.4
(LSB)
0.6
0
–0.2
–0.4
–0.4
–0.6
–0.6
–0.8
–0.8
2000
ADC CODES
3000
4000
–1.0
06020-009
1000
4000
0
–0.2
0
3000
fS = 1MSPS
0.8
0.6
–1.0
2000
ADC CODES
Figure 15. Typical DNL Error, fS = 774 kSPS
fS = 1MSPS
0.8
1000
0
Figure 13. Typical INL Error, fS = 1 MSPS
1000
2000
ADC CODES
3000
4000
06020-012
0.8
06020-011
1.0
Figure 16. Typical DNL Error, fS = 1 MSPS
1.0
0
0
1.0
0.9
–0.1
–0.1
0.9
0.8
–0.2
–0.2
0.8
–0.3
0.7
–0.4
–0.4
0.6
0.5
–0.5
0.4
–0.6
–0.6
–0.7
–0.7
0.3
0.2
–0.8
–0.8
0.2
0.1
–0.9
–0.9
0.1
–1.0
–1.0
0.3
0
1.0
1.5
2.0
2.5
EXTERNAL REFERENCE (V)
3.0
Figure 14. Typical Worst Case INL Error vs. VREF, fS = 774 kSPS
–0.5
0.5
WCP
1.0
1.5
2.0
2.5
EXTERNAL REFERENCE (V)
3.0
0.4
0
Figure 17. Typical Worst Case DNL Error vs. VREF, fS = 774 kSPS
Rev. 0 | Page 21 of 92
06020-013
WCN
06020-010
(LSB)
–0.3
(LSB)
WCP
0.6
(LSB)
0.7
(LSB)
WCN
ADuC7128/ADuC7129
9000
75
8000
–76
70
–78
SNR
7000
65
60
SNR (dB)
FREQUENCY
5000
4000
–82
THD
55
THD (dB)
–80
6000
–84
3000
50
2000
1162
BIN
1163
40
1.0
Figure 18. Code Histogram Plot
0
2.0
2.5
EXTERNAL REFERENCE (V)
–88
3.0
Figure 21. Typical Dynamic Performance vs. VREF
1500
fS = 774kSPS,
SNR = 69.3dB,
THD = –80.8dB,
PHSN = –83.4dB
–20
1.5
06020-017
1161
06020-014
0
–86
45
1000
1450
1400
–40
1350
1300
CODE
(dB)
–60
–80
1250
1200
–100
1150
–120
1100
–140
200
Figure 19. Dynamic Performance, fS = 774 kSPS
20
39.6
39.4
(mA)
–60
–80
39.3
39.2
–120
39.1
–140
39.0
100
FREQUENCY (kHz)
150
200
06020-016
–100
50
150
39.7
39.5
0
100
39.8
–40
–160
50
Figure 22. On-Chip Temperature Sensor Voltage Output vs. Temperature
SNR = 70.4dB,
THD = –77.2dB,
PHSN = –78.9dB
–20
0
TEMPERATURE (°C)
fS = 1MSPS,
0
(dB)
1000
–50
06020-018
100
FREQUENCY (kHz)
Figure 20. Dynamic Performance, fS = 1 MSPS
38.9
–40
0
25
85
TEMPERATURE (°C)
125
Figure 23. Current Consumption vs. Temperature @ CD = 0
Rev. 0 | Page 22 of 92
06020-019
0
06020-015
–160
1050
ADuC7128/ADuC7129
12.05
300
12.00
250
11.95
11.90
200
(µA)
(mA)
11.85
11.80
150
11.75
100
11.70
11.65
50
–40
0
25
85
TEMPERATURE (°C)
125
0
06020-020
11.55
Figure 24. Current Consumption vs. Temperature @ CD = 3
–40
25
85
TEMPERATURE (°C)
125
06020-022
11.60
Figure 26. Current Consumption vs. Temperature in Sleep Mode
7.85
37.4
7.80
37.2
7.75
37.0
(mA)
7.65
7.60
36.8
36.6
7.55
7.50
36.4
7.40
–40
0
25
85
TEMPERATURE (°C)
125
Figure 25. Current Consumption vs. Temperature @ CD = 7
36.2
62.25
125.00
250.00
500.00
SAMPLING FREQUENCY (kSPS)
1000.00
Figure 27. Current Consumption vs. ADC Speed
Rev. 0 | Page 23 of 92
06020-023
7.45
06020-021
(mA)
7.70
ADuC7128/ADuC7129
TERMINOLOGY
ADC SPECIFICATIONS
Integral Nonlinearity
The maximum deviation of any code from a straight line
passing through the endpoints of the ADC transfer function.
The endpoints of the transfer function are zero scale, a point
½ LSB below the first code transition and full scale, a point
½ LSB above the last code transition.
Differential Nonlinearity
The difference between the measured and the ideal 1 LSB
change between any two adjacent codes in the ADC.
Offset Error
The deviation of the first code transition (0000 . . . 000) to
(0000 . . . 001) from the ideal, that is, +½ LSB.
Gain Error
The deviation of the last code transition from the ideal AIN
voltage (full scale − 1.5 LSB) after the offset error has been
adjusted out.
The theoretical signal to (noise + distortion) ratio for an ideal
N-bit converter with a sine wave input is given by
Signal to (Noise + Distortion) = (6.02 N + 1.76) dB
Thus, for a 12-bit converter, this is 74 dB.
Total Harmonic Distortion
The ratio of the rms sum of the harmonics to the fundamental.
DAC SPECIFICATIONS
Relative Accuracy
Otherwise known as endpoint linearity, relative accuracy is
a measure of the maximum deviation from a straight line passing
through the endpoints of the DAC transfer function. It is measured
after adjusting for zero error and full-scale error.
Voltage Output Settling Time
The amount of time it takes for the output to settle to within a
1 LSB level for a full-scale input change.
Signal to (Noise + Distortion) Ratio
The measured ratio of signal to (noise + distortion) at the
output of the ADC. The signal is the rms amplitude of the
fundamental. Noise is the rms sum of all nonfundamental
signals up to half the sampling frequency (fS/2), excluding
dc. The ratio is dependent on the number of quantization
levels in the digitization process; the more levels, the smaller
the quantization noise.
Rev. 0 | Page 24 of 92
ADuC7128/ADuC7129
OVERVIEW OF THE ARM7TDMI CORE
The ARM7 core is a 32-bit reduced instruction set computer
(RISC). It uses a single 32-bit bus for instruction and data. The
length of the data can be 8 bits, 16 bits, or 32 bits. The length of
the instruction word is 32 bits.
The ARM7TDMI is an ARM7 core with the following four
additional features:
•
•
•
•
•
•
•
•
An ARM® instruction is 32-bits long. The ARM7TDMI processor
supports a second instruction set that has been compressed into
16-bits, called the Thumb instruction set. Faster execution from
16-bit memory and greater code density can usually be achieved
by using the Thumb instruction set instead of the ARM instruction
set, which makes the ARM7TDMI core particularly suitable for
embedded applications.
However, the Thumb mode has two limitations:
•
ARM supports five types of exceptions and a privileged processing
mode for each type. The five types of exceptions are
•
T, support for the Thumb® (16-bit) instruction set
D, support for debug
M, support for long multiplications
I, includes the embedded ICE module to support
embedded system debugging
THUMB MODE (T)
•
EXCEPTIONS
Thumb code typically requires more instructions for the
same job. As a result, ARM code is usually best for
maximizing the performance of the time-critical code.
The Thumb instruction set does not include some of the
instructions needed for exception handling, which automatically switches the core to ARM code for exception
handling.
See the ARM7TDMI user guide for details on the core
architecture, the programming model, and both the ARM
and Thumb instruction sets.
LONG MULTIPLY (M)
The ARM7TDMI instruction set includes four extra instructions that perform 32-bit by 32-bit multiplication with 64-bit
result, and 32-bit by 32-bit multiplication-accumulation (MAC)
with 64-bit result. This result is achieved in fewer cycles than
required on a standard ARM7 core.
EMBEDDEDICE (I)
EmbeddedICE provides integrated on-chip support for the core.
The EmbeddedICE module contains the breakpoint and watchpoint registers that allow code to be halted for debugging purposes.
These registers are controlled through the JTAG test port.
Normal interrupt or IRQ. This is provided to service
general-purpose interrupt handling of internal and
external events.
Fast interrupt or FIQ. This is provided to service data
transfer or communication channel with low latency.
FIQ has priority over IRQ.
Memory abort.
Attempted execution of an undefined instruction.
Software interrupt instruction (SWI). This can be used to
make a call to an operating system.
Typically, the programmer defines interrupt as IRQ, but for
higher priority interrupt, that is, faster response time, the
programmer can define interrupt as FIQ.
ARM REGISTERS
ARM7TDMI has a total of 37 registers: 31 general-purpose
registers and six status registers. Each operating mode has
dedicated banked registers.
When writing user-level programs, 15 general-purpose, 32-bit
registers (R0 to R14), the program counter (R15), and the current
program status register (CPSR) are usable. The remaining registers
are used only for system-level programming and exception
handling.
When an exception occurs, some of the standard registers are
replaced with registers specific to the exception mode. All
exception modes have replacement banked registers for the
stack pointer (R13) and the link register (R14), as represented
in Figure 28. The fast interrupt mode has more registers (R8 to
R12) for fast interrupt processing. Interrupt processing can begin
without the need to save or restore these registers and, thus,
saves critical time in the interrupt handling process.
More information relative to the programmer’s model and the
ARM7TDMI core architecture can be found in the following
ARM7TDMI technical and ARM architecture manuals available
directly from ARM Ltd.:
•
•
When a breakpoint or watchpoint is encountered, the processor
halts and enters debug state. Once in a debug state, the processor
registers can be inspected, as well as the Flash/EE, the SRAM,
and the memory mapped registers.
Rev. 0 | Page 25 of 92
DDI0029G, ARM7TDMI Technical Reference Manual
DDI-0100, ARM Architecture Reference Manual
ADuC7128/ADuC7129
R0
USABLE IN USER MODE
R1
At the end of this time, the ARM7TDMI executes the instruction
at Address 0x1C (FIQ interrupt vector address). The maximum
total time is 50 processor cycles, which is just under 1.2 μs in a
system using a continuous 41.78 MHz processor clock.
SYSTEM MODES ONLY
R2
R3
R4
R5
The maximum IRQ latency calculation is similar, but it must
allow for the fact that FIQ has higher priority and could delay
entry into the IRQ handling routine for an arbitrary length of
time. This time can be reduced to 42 cycles if the LDM command
is not used; some compilers have an option to compile without
using this command. Another option is to run the part in Thumb
mode, where the time is reduced to 22 cycles.
R6
R7
R8
R9
R10
R11
R12
R13
R14
R8_FIQ
R9_FIQ
R10_FIQ
R11_FIQ
R12_FIQ
R13_FIQ
R14_FIQ
R13_SVC
R14_SVC
R13_ABT
R14_ABT
R13_IRQ
R14_IRQ
R13_UND
R14_UND
The minimum latency for FIQ or IRQ interrupts is five cycles.
It consists of the shortest time the request can take through the
synchronizer plus the time to enter the exception mode.
R15 (PC)
USER MODE
SPSR_FIQ
FIQ
MODE
SPSR_SVC
SVC
MODE
SPSR_ABT
ABORT
MODE
SPSR_IRQ
IRQ
MODE
SPSR_UND
UNDEFINED
MODE
Figure 28. Register Organization
06020-024
CPSR
Note that the ARM7TDMI always runs in ARM (32-bit) mode
when in privileged modes, that is, when executing interrupt
service routines.
INTERRUPT LATENCY
The worst case latency for an FIQ consists of the following:
•
•
•
•
The longest time the request can take to pass through the
synchronizer
The time for the longest instruction to complete (the
longest instruction is an LDM) that loads all the registers,
including the PC
The time for the data abort entry
The time for FIQ entry
Rev. 0 | Page 26 of 92
ADuC7128/ADuC7129
MEMORY ORGANIZATION
The ADuC7128/ADuC7129 incorporate three separate blocks
of memory: 8 kB of SRAM and two 64 kB of on-chip Flash/EE
memory. There are 126 kB of on-chip Flash/EE memory available
to the user, and the remaining 2 kB are reserved for the factoryconfigured boot page. These two blocks are mapped as shown
in Figure 29.
Note that by default, after a reset, the Flash/EE memory is
mirrored at Address 0x00000000. It is possible to remap the
SRAM at Address 0x00000000 by clearing Bit 0 of the REMAP
MMR. This remap function is described in more detail in the
Flash/EE Memory section.
0xFFFFFFFF
MMRs
0xFFFF0000
RESERVED
0x0009F800
FLASH/EE
0x00080000
RESERVED
The 128 kB of Flash/EE is organized as two banks of 32 k ×
16 bits. In the first block, 31 k × 16 bits are user space and
1 k × 16 bits is reserved for the factory-configured boot
page. The page size of this Flash/EE memory is 512 bytes.
The second 64 kB block is organized in a similar manner. It is
arranged in 32 k × 16 bits. All of this is available as user space.
The 126 kB of Flash/EE is available to the user as code and
nonvolatile data memory. There is no distinction between data
and program as ARM code shares the same space. The real width
of the Flash/EE memory is 16 bits, meaning that in ARM mode
(32-bit instruction), two accesses to the Flash/EE are necessary
for each instruction fetch. Therefore, it is recommended that
Thumb mode be used when executing from Flash/EE memory
for optimum access speed. The maximum access speed for the
Flash/EE memory is 41.78 MHz in Thumb mode and 20.89 MHz
in full ARM mode (see the Execution Time from SRAM and
FLASH/EE section).
SRAM
0x00041FFF
SRAM
The 8 kB of SRAM are available to the user, organized as 2 k ×
32 bits, that is, 2 k words. ARM code can run directly from SRAM
at 41.78 MHz, given that the SRAM array is configured as a
32-bit wide memory array (see the Execution Time from SRAM
and FLASH/EE section).
0x00040000
RESERVED
REMAPPABLE MEMORY SPACE
(FLASH/EE OR SRAM)
0x00000000
06020-025
0x0001FFFF
Figure 29. Physical Memory Map
MEMORY MAPPED REGISTERS
MEMORY ACCESS
The ARM7 core sees memory as a linear array of 232 byte
locations where the different blocks of memory are mapped as
outlined in Figure 29.
The ADuC7128/ADuC7129 memory organization is configured
in little endian format: the least significant byte is located in the
lowest byte address and the most significant byte in the highest
byte address.
BIT 31
FLASH/EE MEMORY
BIT 0
BYTE 3
.
.
.
BYTE 2
.
.
.
BYTE 1
.
.
.
BYTE 0
.
.
.
B
A
9
8
7
6
5
4
0x00000004
3
2
1
0
0x00000000
32 BITS
Figure 30. Little Endian Format
06020-026
0xFFFFFFFF
The memory mapped register (MMR) space is mapped into the
upper two pages of the memory array and accessed by indirect
addressing through the ARM7 banked registers.
The MMR space provides an interface between the CPU and
all on-chip peripherals. All registers except the core registers
reside in the MMR area. All shaded locations shown in Figure 31
are unoccupied or reserved locations and should not be
accessed by user software. See Table 12 through Table 31 for
a full MMR memory map.
The access time reading or writing a MMR depends on the
advanced microcontroller bus architecture (AMBA) bus used to
access the peripheral. The processor has two AMBA buses:
advanced high performance bus (AHB) used for system modules,
and advanced peripheral bus (APB) used for lower performance
peripherals. Access to the AHB is one cycle, and access to the
APB is two cycles. All peripherals on the ADuC7128/ADuC7129
are on the APB except the Flash/EE memory and the GPIOs.
Rev. 0 | Page 27 of 92
ADuC7128/ADuC7129
0xFFFFFFFF
0xFFFF0690
0xFFFF0F80
0xFFFF0F18
QEN
DAC
0xFFFF0F00
0xFFFF0EA8
0xFFFF0544
0xFFFF0500
0xFFFF04A8
0xFFFF0480
0xFFFF0448
0xFFFF0440
0xFFFF0434
0xFFFF0400
0xFFFF0394
0xFFFF0380
0xFFFF0370
0xFFFF0360
0xFFFF0350
0xFFFF0340
0xFFFF0334
0xFFFF0320
ADC
0xFFFF0E80
0xFFFF0E28
BANDGAP
REFERENCE
0xFFFF0E00
0xFFFF0200
0xFFFF0110
0xFFFF0000
FLASH CONTROL
INTERFACE 0
GPIO
0xFFFF0D00
0xFFFF0C30
PLL AND
OSCILLATOR
CONTROL
EXTERNAL MEMORY
0xFFFF0C00
0xFFFF0B54
GENERAL PURPOSE
TIMER 4
PLA
0xFFFF0B00
0xFFFF0A14
WATCHDOG
TIMER
SPI
0xFFFF0A00
0xFFFF0948
WAKEUP
TIMER
I2C1
0xFFFF0900
0xFFFF0848
GENERAL PURPOSE
TIMER
0xFFFF0800
I2C0
0xFFFF076C
TIMER 0
0xFFFF0740
UART1
0xFFFF072C
REMAP AND
SYSTEM CONTROL
Name
REMAP
RSTSTA
RSTCLR
Byte
1
1
1
Access Type
R/W
R
W
Cycle
1
1
1
Table 14. Timer Base Address = 0xFFFF0300
UART0
0xFFFF0700
06020-027
0xFFFF0240
FLASH CONTROL
INTERFACE 1
0xFFFF0D70
POWER SUPPLY
MONITOR
0xFFFF0318
0xFFFF0300
Address
0x0220
0x0230
0x0234
PWM
DDS
0xFFFF0688
0xFFFF0670
Table 13. System Control Base Address = 0xFFFF0200
0xFFFF0FBC
0xFFFF06BC
INTERRUPT
CONTROLLER
Address
0x0300
0x0304
0x0308
0x030C
0x0310
0x0314
0x0320
0x0324
0x0328
0x032C
0x0330
0x0340
0x0344
0x0348
0x034C
0x0360
0x0364
0x0368
0x036C
0x0380
0x0384
0x0388
0x038C
0x0390
Name
T0LD
T0VAL0
T0VAL1
T0CON
T0ICLR
T0CAP
T1LD
T1VAL
T1CON
T1ICLR
T1CAP
T2LD
T2VAL
T2CON
T2ICLR
T3LD
T3VAL
T3CON
T3ICLR
T4LD
T4VAL
T4CON
T4ICLR
T4CAP
Byte
2
2
4
4
1
2
4
4
4
1
4
4
4
4
1
2
2
2
1
4
4
4
1
4
Access Type
R/W
R
R
R/W
W
R
R/W
R
R/W
W
R
R/W
R
R/W
W
R/W
R
R/W
W
R/W
R
R/W
W
R
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Figure 31. Memory Mapped Registers
COMPLETE MMR LISTING
Table 15. PLL Base Address = 0xFFFF0400
Note that the Access Type column corresponds to the access
time reading or writing an MMR. It depends on the AMBA bus
used to access the peripheral. The processor has two AMBA
buses: the AHB (advanced high performance bus) used for
system modules and the APB (advanced peripheral bus) used
for lower performance peripherals.
Table 12. IRQ Base Address = 0xFFFF0000
Address
0x0000
0x0004
0x0008
0x000C
0x0010
0x0100
0x0104
0x0108
0x010C
Name
IRQSTA
IRQSIG
IRQEN
IRQCLR
SWICFG
FIQSTA
FIQSIG
FIQEN
FIQCLR
Byte
4
4
4
4
4
4
4
4
4
Access Type
R
R
R/W
W
W
R
R
R/W
W
Cycle
1
1
1
1
1
1
1
1
1
Address
0x0404
0x0408
0x040C
0x0410
0x0414
0x0418
Name
POWKEY1
POWCON
POWKEY2
PLLKEY1
PLLCON
PLLKEY2
Byte
2
2
2
2
2
2
Access Type
W
R/W
W
W
R/W
W
Cycle
2
2
2
2
2
2
Table 16. PSM Base Address = 0xFFFF0440
Address
0x0440
0x0444
Name
PSMCON
CMPCON
Byte
2
2
Access Type
R/W
R/W
Cycle
2
2
Table 17. Reference Base Address = 0xFFFF0480
Address
0x048C
Rev. 0 | Page 28 of 92
Name
REFCON
Byte
1
Access Type
R/W
Cycle
2
ADuC7128/ADuC7129
Table 18. ADC Base Address = 0xFFFF0500
Address
0x0500
0x0504
0x0508
0x050C
0x0510
0x0514
Name
ADCCON
ADCCP
ADCCN
ADCSTA
ADCDAT
ADCRST
Byte
2
1
1
1
4
1
Access Type
R/W
R/W
R/W
R
R
W
Table 22. I2C0 Base Address = 0xFFFF0800
Cycle
2
2
2
2
2
2
Table 19. DAC and DDS Base Address = 0xFFFF0670
Address
0x0670
0x0690
0x0694
0x0698
0x06A4
0x06B4
0x06B8
0x06BC
Name
DACCON
DDSCON
DDSFRQ
DDSPHS
DACKEY0
DACDAT
DACEN
DACKEY1
Byte
2
1
4
2
1
2
1
1
Access Type
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
Table 20. UART0 Base Address = 0xFFFF0700
Address
0x0700
0x0704
0x0708
0x070C
0x0710
0x0714
0x0718
0x071C
0x0720
0x0724
0x0728
0X072C
Name
COM0TX
COM0RX
COM0DIV0
COM0IEN0
COM0DIV1
COM0IID0
COM0CON0
COM0CON1
COM0STA0
COM0STA1
COM0SCR
COM0IEN1
COM0IID1
COM0ADR
COM0DIV2
Byte
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
Access Type
R/W
R
R/W
R/W
R/W
R
R/W
R/W
R
R
R/W
R/W
R
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Table 21. UART1 Base Address = 0xFFFF0740
Address
0x0740
0x0744
0x0748
0x074C
0x0750
0x0754
0x0758
0x075C
0x0760
0x0764
0x0768
0X076C
Name
COM1TX
COM1RX
COM1DIV0
COM1IEN0
COM1DIV1
COM1IID0
COM1CON0
COM1CON1
COM1STA0
COM1STA1
COM1SCR
COM1IEN1
COM1IID1
COM1ADR
COM1DIV2
Byte
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
Access Type
R/W
R
R/W
R/W
R/W
R
R/W
R/W
R
R
R/W
R/W
R
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Address
0x0800
0x0804
0x0808
0x080C
0x0810
0x0814
0x0818
0x081C
0x0824
0x0828
0x082C
0x0830
0x0838
0x083C
0x0840
0x0844
0x0848
0x084C
Name
I2C0MSTA
I2C0SSTA
I2C0SRX
I2C0STX
I2C0MRX
I2C0MTX
I2C0CNT
I2C0ADR
I2C0BYT
I2C0ALT
I2C0CFG
I2C0DIV
I2C0ID0
I2C0ID1
I2C0ID2
I2C0ID3
I2C0SSC
I2C0FIF
Byte
1
1
1
1
1
1
1
1
1
1
1
2
1
1
1
1
1
1
Access Type
R
R
R
W
R
W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Table 23. I2C1 Base Address = 0xFFFF0900
Address
0x0900
0x0904
0x0908
0x090C
0x0910
0x0914
0x0918
0x091C
0x0924
0x0928
0x092C
0x0930
0x0938
0x093C
0x0940
0x0944
0x0948
0x094C
Name
I2C1MSTA
I2C1SSTA
I2C1SRX
I2C1STX
I2C1MRX
I2C1MTX
I2C1CNT
I2C1ADR
I2C1BYT
I2C1ALT
I2C1CFG
I2C1DIV
I2C1ID0
I2C1ID1
I2C1ID2
I2C1ID3
I2C1SSC
I2C1FIF
Byte
1
1
1
1
1
1
1
1
1
1
1
2
1
1
1
1
1
1
Access Type
R
R
R
W
R
W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Table 24. SPI Base Address = 0xFFFF0A00
Address
0x0A00
0x0A04
0x0A08
0x0A0C
0x0A10
Rev. 0 | Page 29 of 92
Name
SPISTA
SPIRX
SPITX
SPIDIV
SPICON
Byte
1
1
1
1
2
Access Type
R
R
W
R/W
R/W
Cycle
2
2
2
2
2
ADuC7128/ADuC7129
Table 27. GPIO Base Address = 0xFFFF0D00
Table 25. PLA Base Address = 0xFFFF0B00
Address
0x0B00
0x0B04
0x0B08
0x0B0C
0x0B10
0x0B14
0x0B18
0x0B1C
0x0B20
0x0B24
0x0B28
0x0B2C
0x0B30
0x0B34
0x0B38
0x0B3C
0x0B40
0x0B44
0x0B48
0x0B4C
0x0B50
Name
PLAELM0
PLAELM1
PLAELM2
PLAELM3
PLAELM4
PLAELM5
PLAELM6
PLAELM7
PLAELM8
PLAELM9
PLAELM10
PLAELM11
PLAELM12
PLAELM13
PLAELM14
PLAELM15
PLACLK
PLAIRQ
PLAADC
PLADIN
PLAOUT
Byte
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
1
4
4
4
4
Access Type
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Table 26. External Memory Base Address = 0xFFFF0C00
Address
0x0C00
0x0C10
0x0C14
0x0C18
0x0C1C
0x0C20
0x0C24
0x0C28
0x0C2C
Name
XMCFG
XM0CON
XM1CON
XM2CON
XM3CON
XM0PAR
XM1PAR
XM2PAR
XM3PAR
Byte
1
1
1
1
1
2
2
2
2
Access Type
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Cycle
2
2
2
2
2
2
2
2
2
Address
0x0D00
0x0D04
0x0D08
0x0D0C
0x0D10
0x0D20
0x0D24
0x0D28
0x0D2C
0x0D30
0x0D34
0x0D38
0x0D3C
0x0D40
0x0D44
0x0D48
0x0D50
0x0D54
0x0D58
0x0D5C
0x0D60
0x0D64
0x0D68
0x0D6C
Name
GP0CON
GP1CON
GP2CON
GP3CON
GP4CON
GP0DAT
GP0SET
GP0CLR
GP0PAR
GP1DAT
GP1SET
GP1CLR
GP1PAR
GP2DAT
GP2SET
GP2CLR
GP3DAT
GP3SET
GP3CLR
GP3PAR
GP4DAT
GP4SET
GP4CLR
GP4PAR
Byte
4
4
4
4
4
4
1
1
4
4
1
1
4
4
1
1
4
1
1
4
4
1
1
1
Access Type
R/W
R/W
R/W
R/W
R/W
R/W
W
W
R/W
R/W
W
W
R/W
R/W
W
W
R/W
W
W
R/W
R/W
W
W
W
Cycle
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Table 28. Flash/EE Block 0 Base Address = 0xFFFF0E00
Address
0x0E00
0x0E04
0x0E08
0x0E0C
0x0E10
0x0E18
0x0E1C
0x0E20
Name
FEE0STA
FEE0MOD
FEE0CON
FEE0DAT
FEE0ADR
FEE0SGN
FEE0PRO
FEE0HID
Byte
1
1
1
2
2
3
4
4
Access Type
R
R/W
R/W
R/W
R/W
R
R/W
R/W
Cycle
1
1
1
1
1
1
1
1
Table 29. Flash/EE Block 1 Base Address = 0xFFFF0E80
Address
0x0E80
0x0E84
0x0E88
0x0E8C
0x0E90
0x0E98
0x0E9C
0x0EA0
Rev. 0 | Page 30 of 92
Name
FEE1STA
FEE1MOD
FEE1CON
FEE1DAT
FEE1ADR
FEE1SGN
FEE1PRO
FEE1HID
Byte
1
1
1
2
2
3
4
4
Access Type
R
R/W
R/W
R/W
R/W
R
R/W
R/W
Cycle
1
1
1
1
1
1
1
1
ADuC7128/ADuC7129
Table 31. PWM Base Address = 0xFFFF0F80
Table 30. QEN Base Address = 0xFFFF0F00
Address
0x0F00
0x0F04
0x0F08
0x0F0C
0x0F14
0x0F18
Name
QENCON
QENSTA
QENDAT
QENVAL
QENCLR
QENSET
Byte
2
1
2
2
1
1
Access Type
R/W
R
R/W
R
W
W
Cycle
2
2
2
2
2
2
Address
0x0F80
0x0F84
0x0F88
0x0F8C
0x0F90
0x0F94
0x0F98
0x0F9C
0x0FA0
0x0FA4
0x0FA8
0x0FAC
0x0FB0
0x0FB4
0x0FB8
Rev. 0 | Page 31 of 92
Name
PWMCON1
PWM1COM1
PWM1COM2
PWM1COM3
PWM1LEN
PWM2COM1
PWM2COM2
PWM2COM3
PWM2LEN
PWM3COM1
PWM3COM2
PWM3COM3
PWM3LEN
PWMCON2
PWMICLR
Byte
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
Access Type
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
W
Cycle
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
ADuC7128/ADuC7129
ADC CIRCUIT OVERVIEW
The ADC consists of a 12-bit successive approximation converter
based around two capacitor DACs. Depending on the input
signal configuration, the ADC can operate in one of the
following three modes:
•
•
•
Fully differential mode, for small and balanced signals
Single-ended mode, for any single-ended signals
Pseudo differential mode, for any single-ended signals,
taking advantage of the common mode rejection offered by
the pseudo differential input
The converter accepts an analog input range of 0 to VREF when
operating in single-ended mode or pseudo differential mode. In
fully differential mode, the input signal must be balanced around
a common-mode voltage VCM, in the range 0 V to AVDD and
with a maximum amplitude of 2 VREF (see Figure 32).
ADC TRANSFER FUNCTION
Pseudo Differential Mode and Single-Ended Mode
In pseudo differential or single-ended mode, the input range is
0 to VREF. The output coding is straight binary in pseudo
differential and single-ended modes with
1 LSB = FS/4096 or
2.5 V/4096 = 0.61 mV or
610 μV when VREF = 2.5 V
The ideal code transitions occur midway between successive
integer LSB values (that is, 1/2 LSB, 3/2 LSBs, 5/2 LSBs, …,
FS – 3/2 LSBs). The ideal input/output transfer characteristic is
shown in Figure 33.
1111 1111 1111
1111 1111 1110
1111 1111 1101
OUTPUT CODE
The analog-to-digital converter (ADC) incorporates a fast,
multichannel, 12-bit ADC. It can operate from 3.0 V to 3.6 V
supplies and is capable of providing a throughput of up to 1 MSPS
when the clock source is 41.78 MHz. This block provides the
user with a multichannel multiplexer, differential track-andhold, on-chip reference, and ADC.
1111 1111 1100
1LSB =
FS
4096
0000 0000 0011
0000 0000 0010
AVDD
VCM
0000 0000 0000
0V 1LSB
2VREF
+FS – 1LSB
VOLTAGE INPUT
2VREF
Figure 33. ADC Transfer Function in Pseudo Differential Mode or
Single-Ended Mode
06020-028
VCM
0
2VREF
06020-029
0000 0000 0001
VCM
Fully Differential Mode
Figure 32. Examples of Balanced Signals for Fully Differential Mode
A high precision, low drift, and factory-calibrated 2.5 V reference
is provided on-chip. An external reference can also be connected
as described in the Band Gap Reference section.
Single or continuous conversion modes can be initiated in software.
An external CONVST pin, an output generated from the on-chip
PLA, a Timer0, or a Timer1 overflow can also be used to
generate a repetitive trigger for ADC conversions.
If the signal has not been deasserted by the time the ADC
conversion is complete, a second conversion begins automatically.
A voltage output from an on-chip band gap reference proportional to absolute temperature can also be routed through the
front-end ADC multiplexer, effectively an additional ADC
channel input. This facilitates an internal temperature sensor
channel, measuring die temperature to an accuracy of ±3°C.
The amplitude of the differential signal is the difference
between the signals applied to the VIN+ and VIN− pins (that is,
VIN+ − VIN−). The maximum amplitude of the differential signal
is, therefore, −VREF to +VREF p-p (2 × VREF). This is regardless of
the common mode (CM). The common mode is the average of
the two signals (VIN+ + VIN−)/2, and is, therefore, the voltage upon
which the two inputs are centered. This results in the span of
each input being CM ± VREF/2. This voltage has to be set up externally, and its range varies with VREF (see the Driving the Analog
Inputs section).
The output coding is twos complement in fully differential
mode with 1 LSB = 2 VREF/4096 or 2 × 2.5 V/4096 = 1.22 mV
when VREF = 2.5 V. The output result is ±11 bits, but this is
shifted by one to the right. This allows the result in ADCDAT to
be declared as a signed integer when writing C code. The
designed code transitions occur midway between successive
integer LSB values (that is, 1/2 LSB, 3/2 LSBs, 5/2 LSBs, …,
FS − 3/2 LSBs). The ideal input/output transfer characteristic is
shown in Figure 34.
Rev. 0 | Page 32 of 92
ADuC7128/ADuC7129
SIGN
BIT
0 1111 1111 1110
0 1111 1111 1100
Current Consumption
The ADC in standby mode, that is, powered up but not
converting, typically consumes 640 μA. The internal reference
adds 140 μA. During conversion, the extra current is 0.3 μA,
multiplied by the sampling frequency (in kHz).
2 × VREF
4096
1LSB =
0 0000 0000 0001
0 0000 0000 0000
Timing
1 1111 1111 1110
Figure 36 gives details of the ADC timing. Users control the
ADC clock speed and the number of acquisition clock in the
ADCCON MMR. By default, the acquisition time is eight clocks
and the clock divider is two. The number of extra clocks (such
as bit trial or write) is set to 19, giving a sampling rate of 774 kSPS.
For conversion on the temperature sensor, the ADC acquisition
time is automatically set to 16 clocks and the ADC clock divider
is set to 32. When using multiple channels, including the
temperature sensor, the timing settings revert back to the userdefined settings after reading the temperature sensor channel.
1 0000 0000 0100
1 0000 0000 0000
–VREF + 1LSB
0LSB
+VREF – 1LSB
VOLTAGE INPUT (VIN+ – VIN–)
06020-030
1 0000 0000 0010
Figure 34. ADC Transfer Function in Differential Mode
TYPICAL OPERATION
Once configured via the ADC control and channel selection
registers, the ADC converts the analog input and provides
an 11-bit result in the ADC data register.
The top four bits are the sign bits, and the 12-bit result is placed
from Bit 16 to Bit 27, as shown in Figure 35. For fully differential
mode, the result is ±11 bits. Again, it should be noted that in
fully differential mode, the result is represented in twos complement format shifted one bit to the right, and in pseudo differential
and single-ended mode, the result is represented in straight
binary format.
31
27
16 15
ACQ
BIT TRIAL
ADC CLOCK
CONVSTART
ADCBUSY
0
DATA
12-BIT ADC RESULT
06020-031
ADCDAT
SIGN BITS
WRITE
ADCSTA = 0
ADCSTA = 1
Figure 35. ADC Result Format
ADC INTERRUPT
Figure 36. ADC Timing
ADC MMRs Interface
The ADC is controlled and configured via a number of MMRs (see Table 32) that are described in detail in the following pages.
Table 32. ADC MMRs
Name
ADCCON
ADCCP
ADCCN
ADCSTA
ADCDAT
ADCRST
Description
ADC Control Register. Allows the programmer to enable the ADC peripheral, to select the mode of operation of the ADC (either
single-ended, pseudo differential, or fully differential mode), and to select the conversion type (see Table 33).
ADC Positive Channel Selection Register.
ADC Negative Channel Selection Register.
ADC Status Register. Indicates when an ADC conversion result is ready. The ADCSTA register contains only one bit, ADCREADY
(Bit 0), representing the status of the ADC. This bit is set at the end of an ADC conversion generating an ADC interrupt. It is
cleared automatically by reading the ADCDAT MMR. When the ADC is performing a conversion, the status of the ADC can be
read externally via the ADCBusy pin. This pin is high during a conversion. When the conversion is finished, ADCBusy goes back low.
This information can be available on P0.5 (see the General-Purpose I/O section) if enabled in the GP0CON register.
ADC Data Result Register. Holds the 12-bit ADC result, as shown in Table 35.
ADC Reset Register. Resets all the ADC registers to their default values.
Rev. 0 | Page 33 of 92
06020-032
OUTPUT CODE
0 1111 1111 1010
ADuC7128/ADuC7129
Table 33. ADCCON MMR Bit Designations
Bit
12:10
Value
000
001
010
011
100
101
9:8
00
01
10
11
7
6
5
4:3
00
01
10
11
2:0
000
Description
ADC Clock Speed (fADC = FCORE, Conversion = 19 ADC Clocks + Acquisition Time).
fADC/1. This divider is provided to obtain 1 MSPS ADC with an external clock <41.78 MHz.
fADC/2 (default value).
fADC/4.
fADC/8.
fADC/16.
fADC/32.
ADC Acquisition Time (Number of ADC Clocks).
2 clocks.
4 clocks.
8 clocks (default value).
16 clocks.
Enable Conversion.
Set by user to enable conversion mode.
Cleared by user to disable conversion mode.
Reserved. This bit should be set to 0 by the user.
ADC Power Control.
Set by user to place the ADC in normal mode. The ADC must be powered up for at least 5 μs before it converts correctly.
Cleared by user to place the ADC in power-down mode.
Conversion Mode.
Single-ended Mode.
Differential Mode.
Pseudo Differential Mode.
Reserved.
Conversion Type.
Enable CONVST pin as a conversion input.
001
010
011
Enable Timer1 as a conversion input.
Enable Timer0 as a conversion input.
Single Software Conversion. Set to 000 after conversion. Bit 7 of ADCCON MMR should be cleared after starting a single
software conversion to avoid further conversions triggered by the CONVST pin.
100
101
110
Other
Continuous Software Conversion.
PLA Conversion.
PWM Conversion.
Reserved.
Rev. 0 | Page 34 of 92
ADuC7128/ADuC7129
Table 34. ADCCP1 MMR Bit Designations
Table 35. ADCCN1 MMR Bit Designations
Bit
7:5
4:0
Bit
7:5
4:0
Value
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01011
01100
01101
01110
01111
10000
10001
10010
10011
Others
1
2
Description
Reserved
Positive Channel Selection Bits
ADC0
ADC1
ADC2
ADC3
ADC4
ADC5
ADC6
ADC7
ADC8
ADC9
ADC10
ADC11
ADC12/LD2TX2
ADC13/LD1TX2
Reserved
Reserved
Temperature Sensor
AGND
Reference
AVDD/2
Reserved
1
Value
00000
00001
00010
00011
00100
00101
00110
Description
Reserved
Negative Channel Selection Bits
ADC0
ADC1
ADC2
ADC3
ADC4
ADC5
ADC6
00111
01000
01001
01010
01011
01100
01101
01110
01111
10000
Others
ADC7
ADC8
ADC9
ADC10
ADC11
ADC12/LD2TX
ADC13/LD1TX
Reserved
Reserved
Temperature Sensor
Reserved
ADC channel availability depends on part model.
Table 36. ADCSTA MMR Bit Designations
ADC channel availability depends on part model.
Because ADC12 and ADC13 are shared with the line driver TX pins, a high
level of crosstalk is seen on these pins when used in ADC mode.
Bit
0
Value
1
0
0
Description
Indicates that an ADC conversion is complete.
It is set automatically once an ADC conversion
completes.
Automatically cleared by reading the
ADCDAT MMR.
Table 37. ADCDAT MMR Bit Designations
Bit
27:16
Value
Description
Holds the ADC result (see Figure 35).
Table 38. ADCRST MMR Bit Designations
Bit
0
Rev. 0 | Page 35 of 92
Value
1
Description
Set to 1 by the user to reset all the ADC
registers to their default values.
ADuC7128/ADuC7129
CONVERTER OPERATION
Pseudo Differential Mode
The ADC incorporates a successive approximation (SAR)
architecture involving a charge-sampled input stage. This
architecture is described for the three different modes of
operation: differential mode, pseudo differential mode, and
single-ended mode.
In pseudo differential mode, Channel− is linked to the VIN− pin
of the ADuC7128/ADuC7129, and SW2 switches between A
(Channel−) and B (VREF). The VIN− pin must be connected to
ground or a low voltage. The input signal on VIN+ can then vary
from VIN− to VREF + VIN−. Note that VIN− must be chosen so that
VREF + VIN− does not exceed AVDD.
The ADuC7128/ADuC7129 contain a successive approximation
ADC based on two capacitive DACs. Figure 37 and Figure 38
show simplified schematics of the ADC in acquisition and
conversion phase, respectively. The ADC comprises control logic,
a SAR, and two capacitive DACs. In Figure 37 (the acquisition
phase), SW3 is closed and SW1 and SW2 are in Position A. The
comparator is held in a balanced condition, and the sampling
capacitor arrays acquire the differential signal on the input.
AIN0
MUX
AIN13
B
CS
A SW1
CHANNEL– A SW2
CS
A SW1
MUX
A
AIN13
SW2
CS
COMPARATOR
SW3
CONTROL
LOGIC
B
VREF
VIN–
CAPACITIVE
DAC
CHANNEL–
In single-ended mode, SW2 is always connected internally to
ground. The VIN− pin can be floating. The input signal range on
VIN+ is 0 V to VREF.
CONTROL
LOGIC
Figure 37. ADC Acquisition Phase
When the ADC starts a conversion (see Figure 38), SW3 opens
and SW1 and SW2 move to Position B, causing the comparator
to become unbalanced. Both inputs are disconnected once the
conversion begins. The control logic and the charge redistribution
DACs are used to add and subtract fixed amounts of charge
from the sampling capacitor arrays to bring the comparator
back into a balanced condition. When the comparator is
rebalanced, the conversion is complete. The control logic generates
the ADC output code. The output impedances of the sources
driving the VIN+ pin and the VIN− pin must be matched; otherwise,
the two inputs have different settling times, resulting in errors.
CAPACITIVE
DAC
CHANNEL+
MUX
B
CS
A SW1
CHANNEL– A SW2
CS
COMPARATOR
SW3
CONTROL
LOGIC
B
VREF
Figure 38. ADC Conversion Phase
CAPACITIVE
DAC
06020-034
AIN0
CAPACITIVE
DAC
CHANNEL+
AIN0
MUX
AIN13
B
CS
A SW1
CS
COMPARATOR
SW3
CONTROL
LOGIC
CHANNEL–
CAPACITIVE
DAC
06020-036
CAPACITIVE
DAC
06020-033
B
VREF
AIN13
CS
B
Single-Ended Mode
COMPARATOR
SW3
CHANNEL+
AIN0
Figure 39. ADC in Pseudo Differential Mode
CAPACITIVE
DAC
CHANNEL+
CAPACITIVE
DAC
06020-035
Differential Mode
Figure 40. ADC in Single-Ended Mode
Analog Input Structure
Figure 41 shows the equivalent circuit of the analog input
structure of the ADC. The four diodes provide ESD protection
for the analog inputs. Care must be taken to ensure that the
analog input signals never exceed the supply rails by more than
300 mV. Voltage in excess of 300 mV would cause these diodes to
become forward biased and start conducting into the substrate.
These diodes can conduct up to 10 mA without causing
irreversible damage to the part.
The C1 capacitors in Figure 41 are typically 4 pF and can be
primarily attributed to pin capacitance. The resistors are lumped
components made up of the on resistance of the switches. The
value of these resistors is typically about 100 Ω. The C2 capacitors
are the ADC sampling capacitors and have a capacitance of 16 pF
typical.
Rev. 0 | Page 36 of 92
ADuC7128/ADuC7129
AVDD
D
C1
Table 39. VCM Ranges
AVDD
3.3 V
R1 C2
D
3.0 V
AVDD
D
Figure 41. Equivalent Analog Input Circuit
Conversion Phase: Switches Open, Track Phase: Switches Closed
For ac applications, removing high frequency components from
the analog input signal is recommended through the use of an
RC low-pass filter on the relevant analog input pins. In applications
where harmonic distortion and signal-to-noise ratio are critical,
the analog input should be driven from a low impedance source.
Large source impedances significantly affect the ac performance
of the ADC and can necessitate the use of an input buffer amplifier.
The choice of the op amp is a function of the particular application.
Figure 42 and Figure 43 give an example of an ADC front end.
VCM Max
2.05 V
2.276 V
2.55 V
1.75 V
1.976 V
2.25 V
Signal Peak-to-Peak
2.5 V
2.048 V
1.25 V
2.5 V
2.048 V
1.25 V
The ADuC7128/ADuC7129 provide a voltage output from an
on-chip band gap reference proportional to absolute temperature.
The voltage output can also be routed through the front end
ADC multiplexer (effectively an additional ADC channel
input), facilitating an internal temperature sensor channel,
measuring die temperature to an accuracy of ±3°C.
The following is a code example of how to configure the ADC
for use with the temperature sensor:
int main(void)
{
float a = 0;
short b;
ADCCON = 0x20;
ADuC7128
// power-on the ADC
delay(2000);
ADC0
ADCCP = 0x10; // Select Temperature Sensor as
// an input to the ADC
06020-038
10Ω
VCM Min
1.25 V
1.024 V
0.75 V
1.25 V
1.024 V
0.75 V
TEMPERATURE SENSOR
D
06020-037
C1
R1 C2
VREF
2.5 V
2.048 V
1.25 V
2.5 V
2.048 V
1.25 V
0.01µF
REFCON = 0x01;// connect internal 2.5V
// reference to Vref pin
Figure 42. Buffering Single-Ended/Pseudo Differential Input
ADCCON = 0xE4;// continuous conversion
while(1)
ADuC7128
{
ADC0
VREF
while (!ADCSTA){};
06020-039
ADC1
b = (ADCDAT >> 16);
// To calculate temperature in °C, use
the formula:
Figure 43. Buffering Differential Inputs
When no amplifier is used to drive the analog input, the source
impedance should be limited to values lower than 1 kΩ. The
maximum source impedance depends on the amount of total
harmonic distortion (THD) that can be tolerated. The THD
increases as the source impedance increases and the
performance degrades.
a = 0x525 - b;
// ((Temperature = 0x525 - Sensor
Voltage) / 1.3)
a /= 1.3;
b = floor(a);
printf("Temperature: %d oC\n",b);
DRIVING THE ANALOG INPUTS
}
Internal or external reference can be used for the ADC. In
differential mode of operation, there are restrictions on the
common-mode input signal (VCM) that are dependent on
reference value and supply voltage used to ensure that the signal
remains within the supply rails. Table 39 gives some calculated
VCM minimum and VCM maximum values.
return 0;
}
Rev. 0 | Page 37 of 92
ADuC7128/ADuC7129
BAND GAP REFERENCE
The ADuC7128/ADuC7129 provide an on-chip band gap
reference of 2.5 V that can be used for the ADC and for the
DAC. This internal reference also appears on the VREF pin.
When using the internal reference, a capacitor of 0.47 μF must
be connected from the external VREF pin to AGND to ensure
stability and fast response during ADC conversions. This
reference can also be connected to an external pin (VREF)
and used as a reference for other circuits in the system.
An external buffer is required because of the low drive capability
of the VREF output. A programmable option also allows an external
reference input on the VREF pin. Note that it is not possible to
disable the internal reference. Therefore, the external reference
source must be capable of overdriving the internal reference source.
The band gap reference interface consists of an 8-bit REFCON
MMR, described in Table 40.
Table 40. REFCON MMR Bit Designations
Bit
7:1
0
Description
Reserved.
Internal Reference Output Enable.
Set by user to connect the internal 2.5 V reference to the VREF pin. The reference can be used for external components but needs
to be buffered.
Cleared by user to disconnect the reference from the VREF pin.
Note: The on-chip DAC is functional only with the internal reference output enable bit set. It does not work with an external
reference.
Rev. 0 | Page 38 of 92
ADuC7128/ADuC7129
NONVOLATILE FLASH/EE MEMORY
Like EEPROM, Flash memory can be programmed in-system
at a byte level, although it must first be erased. The erase is
performed in page blocks. As a result, Flash memory is often,
and more correctly, referred to as Flash/EE memory.
Overall, Flash/EE memory represents a step closer to the ideal
memory device that includes nonvolatility, in-circuit
programmability, high density, and low cost. Incorporated in
the ADuC7128/ADuC7129, Flash/EE memory technology
allows the user to update program code space in-circuit,
without the need to replace one-time programmable (OTP)
devices at remote operating nodes.
FLASH/EE MEMORY
The ADuC7128/ADuC7129 contain two 64 kB arrays of
Flash/EE memory. In the first block, the lower 62 kB are
available to the user and the upper 2 kB of this Flash/EE
program memory array contain permanently embedded
firmware, allowing in-circuit serial download. The 2 kB of
embedded firmware also contain a power-on configuration
routine that downloads factory calibrated coefficients to the
various calibrated peripherals, such as band gap references.
This 2 kB embedded firmware is hidden from user code. It is not
possible for the user to read, write, or erase this page. In the second
block, all 64 kB of Flash/EE memory are available to the user.
Retention quantifies the ability of the Flash/EE memory to
retain its programmed data over time. Again, the parts are
qualified in accordance with the formal JEDEC Retention
Lifetime Specification (A117) at a specific junction temperature
(TJ = 85°C). As part of this qualification procedure, the
Flash/EE memory is cycled to its specified endurance limit,
described previously, before data retention is characterized.
This means that the Flash/EE memory is guaranteed to retain
its data for its fully specified retention lifetime every time the
Flash/EE memory is reprogrammed. Note, too, that retention
lifetime, based on an activation energy of 0.6 eV, derates with
TJ, as shown in Figure 44.
600
450
300
150
The 126 kB of Flash/EE memory can be programmed in-circuit,
using the serial download mode or the JTAG mode provided.
0
04955-085
The ADuC7128/ADuC7129 incorporate Flash/EE memory
technology on-chip to provide the user with nonvolatile, incircuit reprogrammable memory space.
As indicated in Table 1 of the Specifications section, the
Flash/EE memory endurance qualification is carried out in
accordance with JEDEC Retention Lifetime Specification A117
over the industrial temperature range of –40° to +125°C. The
results allow the specification of a minimum endurance figure
over a supply temperature of 10,000 cycles.
RETENTION (Years)
FLASH/EE MEMORY OVERVIEW
30
Flash/EE Memory Reliability
The Flash/EE memory arrays on the parts are fully qualified for
two key Flash/EE memory characteristics: Flash/EE memory
cycling endurance and Flash/EE memory data retention.
Endurance quantifies the ability of the Flash/EE memory to be
cycled through many program, read, and erase cycles. A single
endurance cycle is composed of four independent, sequential
events, defined as
1.
2.
3.
4.
Initial page erase sequence
Read/verify, sequence a single Flash/EE location
Byte program sequence memory
Second read/verify sequence endurance cycle
In reliability qualification, every half word (16-bit wide)
location of the three pages (top, middle, and bottom) in
the Flash/EE memory is cycled 10,000 times from 0x0000
to 0xFFFF.
40
55
70
85
100
125
JUNCTION TEMPERATURE (°C)
135
150
Figure 44. Flash/EE Memory Data Retention
Serial Downloading (In-Circuit Programming)
The ADuC7128/ADuC7129 facilitate code download via the
standard UART serial port. The ADuC7128/ADuC7129 enter
serial download mode after a reset or power cycle if the BM pin
is pulled low through an external 1 kΩ resistor. Once in serial
download mode, the user can download code to the full 126 kB
of Flash/EE memory while the device is in-circuit in its target application hardware. A PC serial download executable is provided as
part of the development system for serial downloads via the UART.
For additional information, an application note is available at
www.analog.com/microconverter describing the protocol for
serial downloads via the UART.
JTAG Access
The JTAG protocol uses the on-chip JTAG interface to
facilitate code download and debug.
Rev. 0 | Page 39 of 92
ADuC7128/ADuC7129
FLASH/EE MEMORY SECURITY
The 126 kB of Flash/EE memory available to the user can be
read and write protected. Bit 31 of the FEE0PRO/FEE0HID MMR
protects the 126 kB from being read through JTAG and also in
parallel programming mode. The other 31 bits of this register
protect writing to the Flash/EE memory; each bit protects four
pages, that is, 2 kB. Write protection is activated for all access types.
FEE1PRO and FEE1HID similarly protect the second 64 kB block.
All 32 bits of this are used to protect four pages at a time.
Three Levels of Protection
The Flash/EE memory can be permanently protected by using
the FEEPRO MMR and a particular value of the 0xDEADDEAD
key. Entering the key again to modify the FEExPRO register is
not allowed.
Sequence to Write the Key
3.
4.
5.
//Protect pages 4 to 7
//Write key enable
//16 bit key value
//16 bit key value
// Write key command
The same sequence should be followed to protect the part
permanently with FEExADR = 0xDEAD and FEExDAT =
0xDEAD.
FEE0DAT Register
Protection can be set by writing into FEExPRO MMR. It takes
effect only after a save protection command (0x0C) and a reset.
The FEExPRO MMR is protected by a key to avoid direct access.
The key is saved once and must be entered again to modify
FEExPRO. A mass erase sets the key back to 0xFFFF but also
erases all the user code.
2.
FEE0PRO=0xFFFFFFFD;
FEE0MOD=0x48;
FEE0ADR=0x1234;
FEE0DAT=0x5678;
FEE0CON= 0x0C;
FLASH/EE CONTROL INTERFACE
Protection can be set and removed by writing directly into
FEExHID MMR. This protection does not remain after reset.
1.
The sequence to write the key is shown in the following example;
this protects writing Page 4 to Page 7 of the Flash/EE memory:
Name
FEE0DAT
Address
0xFFFF0E0C
Default Value
0xXXXX
Access
R/W
FEE0DAT is a 16-bit data register.
FEE0ADR Register
Name
FEE0ADR
Address
0xFFFF0E10
Default Value
0x0000
Access
R/W
FEE0ADR is a 16-bit address register.
FEE0SGN Register
Name
FEE0SGN
Address
0xFFFF0E18
Default Value
0xFFFFFF
Access
R
FEE0SGN is a 24-bit code signature.
Write the bit in FEExPRO corresponding to the page to be
protected.
Enable key protection by setting Bit 6 of FEExMOD (Bit 5
must equal 0).
Write a 32-bit key in FEExADR, FEExDAT.
Run the write key command 0×0C in FEExCON; wait for
the read to be successful by monitoring FEExSTA.
Reset the part.
To remove or modify the protection, the same sequence is used
with a modified value of FEExPRO. If the key chosen is the value
0xDEAD, then the memory protection cannot be removed. Only
a mass erase unprotects the part, but it also erases all user code.
FEE0PRO Register
Name
FEE0PRO
Address
0xFFFF0E1C
Default Value
0x00000000
Access
R/W
FEE0PRO provides protection following subsequent reset MMR.
It requires a software key (see Table 44).
FEE0HID Register
Name
FEE0HID
Address
0xFFFF0E20
Default Value
0xFFFFFFFF
Access
R/W
FEE0HID provides immediate protection MMR. It does not
require any software keys (see Table 44).
Command Sequence for Executing a Mass Erase
FEE0DAT = 0x3CFF;
FEE0ADR = 0xFFC3;
FEE0MOD = FEE0MOD|0x8;
//Erase key enable
FEE0CON = 0x06;
//Mass erase command
Rev. 0 | Page 40 of 92
ADuC7128/ADuC7129
FEE1DAT Register
Name
FEE1DAT
Address
0xFFFF0E8C
FEE0STA Register
Default Value
0xXXXX
Access
R/W
FEE1DAT is a 16-bit data register.
Address
0xFFFF0E90
Default Value
0x0000
Address
0xFFFF0E00
Access
R/W
Name
FEE1STA
Address
0xFFFF0E80
FEE1ADR is a 16-bit address register.
FEE0MOD Register
FEE1SGN Register
Name
FEE0MOD
Name
FEE1SGN
Address
0xFFFF0E98
Default Value
0xFFFFFF
Access
R
FEE1SGN is a 24-bit code signature.
Address
0xFFFF0E9C
Default Value
0x00000000
Access
R/W
FEE1PRO provides protection following subsequent reset MMR.
It requires a software key (see Table 45).
FEE1HID Register
Name
FEE1HID
Address
0xFFFF0EA0
Default Value
0xFFFFFFFF
Access
R/W
Default Value
0x0000
Access
R/W
Access
R/W
Address
0xFFFF0E04
Default Value
0x80
Access
R/W
Default Value
0x80
Access
R/W
Default Value
0x0000
Access
R/W
Default Value
0x0000
Access
R/W
FEE1MOD Register
Name
FEE1MOD
FEE1PRO Register
Name
FEE1PRO
Default Value
0x0000
FEE1STA Register
FEE1ADR Register
Name
FEE1ADR
Name
FEE0STA
Address
0xFFFF0E84
FEE0CON Register
Name
FEE0CON
Address
0xFFFF0E08
FEE1CON Register
Name
FEE1CON
FEE1HID provides immediate protection MMR. It does not
require any software keys (see Table 45).
Rev. 0 | Page 41 of 92
Address
0xFFFF0E88
ADuC7128/ADuC7129
Table 41. FEExSTA MMR Bit Designations
Bit
15:6
5
4
3
2
1
0
Description
Reserved.
Reserved.
Reserved.
Flash/EE Interrupt Status Bit.
Set automatically when an interrupt occurs, that is, when a command is complete and the Flash/EE interrupt enable bit in the
FEExMOD register is set.
Cleared when reading FEExSTA register.
Flash/EE Controller Busy.
Set automatically when the controller is busy.
Cleared automatically when the controller is not busy.
Command Fail.
Set automatically when a command completes unsuccessfully.
Cleared automatically when reading FEExSTA register.
Command Complete.
Set by MicroConverter when a command is complete.
Cleared automatically when reading FEExSTA register.
Table 42. FEExMOD MMR Bit Designations
Bit
7:5
4
3
2
1:0
Description
Reserved.
Flash/EE Interrupt Enable.
Set by user to enable the Flash/EE interrupt. The interrupt occurs when a command is complete.
Cleared by user to disable the Flash/EE interrupt
Erase/Write Command Protection.
Set by user to enable the erase and write commands.
Cleared to protect the Flash/EE memory against erase/write command.
Reserved. Should always be set to 0 by the user.
Flash/EE Wait States. Both Flash/EE blocks must have the same wait state value for any change to take effect.
Table 43. Command Codes in FEExCON
Code
0x00 1
0x011
0x021
0x031
Command
Null
Single read
Single write
Erase/Write
0x041
Single verify
0x051
0x061
Single erase
Mass erase
0x07
0x08
0x09
0x0A
0x0B
0x0C
Reserved
Reserved
Reserved
Reserved
Signature
Protect
0x0D
0x0E
0x0F
Reserved
Reserved
Ping
1
Description
Idle State.
Load FEExDAT with the 16-bit data indexed by FEExADR.
Write FEExDAT at the address pointed by FEExADR. This operation takes 50 μs.
Erase the page indexed by FEExADR and write FEExDAT at the location pointed by FEExADR. This operation
takes 20 ms.
Compare the contents of the location pointed by FEExADR to the data in FEExDAT. The result of the comparison
is returned in FEExSTA Bit 1.
Erase the page indexed by FEExADR.
Erase user space. The 2 kB of kernel are protected in Block 0. This operation takes 2.48 sec. To prevent accidental
execution, a command sequence is required to execute this instruction.
Reserved.
Reserved.
Reserved.
Reserved.
Gives a signature of the 64 kB of Flash/EE in the 24-bit FEExSIGN MMR. This operation takes 32,778 clock cycles.
This command can be run only once. The value of FEExPRO is saved and can be removed only with a mass erase
(0x06) or with the key.
Reserved.
Reserved.
No Operation, Interrupt Generated.
The FEExCON register always reads 0x07 immediately after execution of any of these commands.
Rev. 0 | Page 42 of 92
ADuC7128/ADuC7129
Table 44. FEE0PRO and FEE0HID MMR Bit Designations
Bit
31
30:0
Description
Read Protection.
Cleared by user to protect Block 0.
Set by user to allow reading Block 0.
Write Protection for Page 123 to Page 120, for Page 119 to Page 116, and for Page 3 to Page 0.
Cleared by user to protect the pages in writing.
Set by user to allow writing the pages.
Table 45. FEE1PRO and FEE1HID MMR Bit Designations
Bit
31
30
31:0
Description
Read Protection.
Cleared by user to protect Block 1.
Set by user to allow reading Block 1.
Write Protection for Page 127 to Page 120.
Cleared by user to protect the pages in writing.
Set by user to allow writing the pages.
Write Protection for Page 119 to Page 116 and for Page 3 to Page 0.
Cleared by user to protect the pages in writing.
Set by user to allow writing the pages.
EXECUTION TIME FROM SRAM AND FLASH/EE
This section describes SRAM and Flash/EE access times during
execution for applications where execution time is critical.
Execution from SRAM
Fetching instructions from SRAM takes one clock cycle because
the access time of the SRAM is 2 ns and a clock cycle is 22 ns
minimum. However, if the instruction involves reading or
writing data to memory, one extra cycle must be added if the
data is in SRAM (or three cycles if the data is in Flash/EE), one
cycle to execute the instruction and two cycles to get the 32-bit
data from Flash/EE. A control flow instruction, such as a branch
instruction, takes one cycle to fetch, but it also takes two cycles
to fill the pipeline with the new instructions.
Timing is identical in both modes when executing instructions
that involve using the Flash/EE for data memory. If the instruction
to be executed is a control flow instruction, an extra cycle is
needed to decode the new address of the program counter and
then four cycles are needed to fill the pipeline. A data processing
instruction involving only core registers doesn’t require any
extra clock cycles, but if it involves data in Flash/EE, an extra
clock cycle is needed to decode the address of the data and two
cycles to get the 32-bit data from Flash/EE. An extra cycle must
also be added before fetching another instruction. Data transfer
instructions are more complex and are summarized in Table 46.
Table 46. Execution Cycles in ARM/Thumb Mode
Fetch
Cycles
2/1
2/1
2/1
2/1
2/1
2/1
Dead
Time
1
1
N
1
1
N
Because the Flash/EE width is 16 bits and access time for 16-bit
words is 23 ns, execution from Flash/EE cannot be done in one
cycle (as can be done from SRAM when the CD bit = 0). In addition, some dead times are needed before accessing data for any
value of CD bits.
In ARM mode, where instructions are 32 bits, two cycles are
needed to fetch any instruction when CD = 0. In Thumb mode,
where instructions are 16 bits, one cycle is needed to fetch any
instruction.
With 1 < N ≤ 16, N is the number of bytes of data to load or
store in the multiple load/store instruction. The SWAP instruction
combines an LD and STR instruction with only one fetch,
giving a total of eight cycles plus 40 μs.
Execution from Flash/EE
Rev. 0 | Page 43 of 92
Data Access
2
1
2×N
2 × 20 μs
20 μs
2 × N × 20 μs
Dead
Time
1
1
N
1
1
N
Instructions
LD
LDH
LDM/PUSH
STR
STRH
STRM/POP
ADuC7128/ADuC7129
RESET AND REMAP
Remap Operation
The ARM exception vectors are all situated at the bottom of the
memory array, from Address 0x00000000 to Address 0x00000020,
as shown in Figure 45.
When a reset occurs on the ADuC7128/ADuC7129, execution
starts automatically in factory-programmed internal configuration code. This kernel is hidden and cannot be accessed by user
code. If the ADuC7128/ADuC7129 are in normal mode (the BM
pin is high), they execute the power-on configuration routine of
the kernel and then jump to the reset vector Address 0x00000000 to
execute the user’s reset exception routine. Because the Flash/EE is
mirrored at the bottom of the memory array at reset, the reset
interrupt routine must always be written in Flash/EE.
0xFFFFFFFF
KERNEL
0x0008FFFF
FLASH/EE
INTERRUPT
SERVICE ROUTINES
The remap is done from Flash/EE by setting Bit 0 of the REMAP
register. Precautions must be taken to execute this command
from Flash/EE, above Address 0x00080020, and not from the
bottom of the array because this is replaced by the SRAM.
0x00080000
0x00041FFF
INTERRUPT
SERVICE ROUTINES
SRAM
0x00040000
0x00000020
0x00000000
0x00000000
06020-040
MIRROR SPACE
ARM EXCEPTION
VECTOR ADDRESSES
Figure 45. Remap for Exception Execution
This operation is reversible: the Flash/EE can be remapped at
Address 0x00000000 by clearing Bit 0 of the REMAP MMR.
Precaution must again be taken to execute the remap function
from outside the mirrored area. Any kind of reset remaps the
Flash/EE memory at the bottom of the array.
Reset Operation
By default and after any reset, the Flash/EE is mirrored at the
bottom of the memory array. The remap function allows the
programmer to mirror the SRAM at the bottom of the memory
array, facilitating execution of exception routines from SRAM
instead of from Flash/EE. This means exceptions are executed
twice as fast, with the exception being executed in ARM mode
(32 bits), and the SRAM being 32 bits wide instead of 16-bit
wide Flash/EE memory.
There are four kinds of reset: external reset, power-on reset,
watchdog expiration, and software force. The RSTSTA register
indicates the source of the last reset and RSTCLR clears the
RSTSTA register. These registers can be used during a reset
exception service routine to identify the source of the reset.
If RSTSTA is null, the reset was external. Note that when
clearing RSTSTA, all bits that are currently 1 must be cleared.
Otherwise, a reset event occurs.
Table 47. REMAP MMR Bit Designations
Bit
0
Name
Remap
Description
Remap Bit.
Set by user to remap the SRAM to Address 0x00000000.
Cleared automatically after reset to remap the Flash/EE memory to Address 0x00000000.
Table 48. RSTSTA MMR Bit Designations
Bit
7:3
2
1
0
Description
Reserved.
Software Reset.
Set by user to force a software reset.
Cleared by setting the corresponding bit in RSTCLR.
Watchdog Timeout.
Set automatically when a watchdog timeout occurs.
Cleared by setting the corresponding bit in RSTCLR.
Power-On Reset.
Set automatically when a power-on reset occurs.
Cleared by setting the corresponding bit in RSTCLR.
Rev. 0 | Page 44 of 92
ADuC7128/ADuC7129
OTHER ANALOG PERIPHERALS
DAC
The ADuC7128/ADuC7129 feature a 10-bit current DAC that
can be used to generate user-defined waveforms or sine waves
generated by the DDS. The DAC consists of a 10-bit IDAC
followed by a current-to-voltage conversion.
The current output of the IDAC is passed through a resistor and
capacitor network where it is both filtered and converted to a
voltage. This voltage is then buffered by an op amp and passed
to the line driver.
For the DAC to function, the internal 2.5 V voltage reference
must be enabled and driven out onto an external capacitor,
REFCON = 0x01.
Once the DAC is enabled, users see a 5 mV drop in the internal
reference value. This is due to bias currents drawn from the
reference used in the DAC circuitry. It is recommended that if
using the DAC, it be left powered on to avoid seeing variations
in ADC results.
Table 49. DACCON MMR Bit Designations
Bit
Value
10:9
8
7
6
5
4
3
2:1
00
01
10
11
0
Description
Reserved. These bits should be written to 0 by the user.
Reserved. This bit should be written to 0 by the user.
Reserved. This bit should be written to 0 by the user.
Reserved. This bit should be written to 0 by the user.
Output Enable. This bit operates in all modes. In Line Driver mode, this bit should be set.
Set by user to enable the line driver output.
Cleared by user to disable the line driver output. In this mode the line driver output is high impedance.
Single-Ended or Differential Output Control.
Set by user to operate in differential mode, the output is the differential voltage between LD1TX and LD2TX. The voltage
output range is VREF/2 ± VREF/2.
Cleared by user to reference the LD1TX output to AGND. The voltage output range is AVDD/2 ± VREF/2.
Reserved. This bit should be set to 0 by the user.
Operation Mode Control. This bit selects the mode of operation of the DAC.
Power-Down.
Reserved.
Reserved.
DDS and DAC Mode. Selected by DACEN.
DAC Update Rate Control. This bit has no effect when in DDS mode.
Set by user to update the DAC on the negative edge of Timer1. This allows the user to use any one of the core CLK, OSC
CLK, baud CLK, or user CLK and divide these down by 1, 16, 256, or 32,768. A user can do waveform generation by
writing to the DAC data register from RAM and updating the DAC at regular intervals via Timer1.
Cleared by user to update the DAC on the negative edge of HCLK.
Rev. 0 | Page 45 of 92
ADuC7128/ADuC7129
DACEN Register
Name
DACEN
Address
0xFFFF06B8
Default Value
0x00
Access
R/W
Table 50. DACEN MMR Bit Designations
Bit
7:1
0
DACEN and DACDAT require key access. To write to these
MMRs, use the sequences shown in Table 52.
Description
Reserved.
Set to 1 by the user to enable DAC mode.
Set to 0 by the user to enable DDS mode.
Table 52. DACEN and DACDAT Write Sequences
DACDAT Register
Name
DACDAT
Address
0xFFFF06B4
Default Value
0x0000
Table 51. DACDAT MMR Bit Designations
Bit
15:10
9:0
Description
Reserved.
10-bit data for DAC.
The DACDAT MMR controls the output of the DAC. The data
written to this register is a ±9-bit signed value. This means that
0x0000 represents midscale, 0x0200 represents zero scale, and
0x01FF represents full scale.
Access
R/W
DACEN
DACKEY0 = 0x07
DACEN = user value
DACKEY1 = 0xB9
DDS
The DDS is used to generate a digital sine wave signal for the
DAC on the ADuC7128/ADuC7129. It can be enabled into
a free running mode by the user.
Both the phase and frequency can be controlled.
Table 53. DDSCON MMR Bit Designations
Bit
7:6
5
4
3:0
DACDAT
DACKEY0 = 0x07
DACDAT = user value
DACKEY1 = 0xB9
Description
Reserved.
DDS Output Enable.
Set by user to enable the DDS output. This has an effect only if the DDS is selected in DACCON.
Cleared by user to disable the DDS output.
Reserved.
Binary Divide Control.
DIV
Scale Ratio
0000
0.000
0001
0.125
0010
0.250
0011
0.375
0100
0.500
0101
0.625
0110
0.750
0111
0.875
1xxx
1.000
Rev. 0 | Page 46 of 92
ADuC7128/ADuC7129
DDSFRQ Register
Address
0xFFFF0694
Default Value
0x00000000
Access
R/W
Table 54. DDSFRQ MMR Bit Designations
The PSM does not operate correctly when using JTAG debug.
It should be disabled in JTAG debug mode.
Description
Frequency select word (FSW)
The DDS frequency is controlled via the DDSFRQ MMR. This
MMR contains a 32-bit word (FSW) that controls the frequency
according to the following formula:
Frequency =
FSW × 20.8896 MHz
232
DDSPHS Register
Name
DDSPHS
Address
0xFFFF0698
Default Value
0x00000000
Access
R/W
COMPARATOR
The ADuC7128/ADuC7129 integrate an uncommitted voltage
comparator. The positive input is multiplexed with ADC2, and
the negative input has two options: ADC3 or the internal reference. The output of the comparator can be configured to generate
a system interrupt, can be routed directly to the programmable
logic array, can start an ADC conversion, or can be on an
external pin, CMPOUT.
Table 55. DDSPHS MMR Bit Designations
Bit
31:12
11:0
ADC2/CMP0
Description
Reserved
Phase
ADC3/CMP1
MUX
PLA
IRQ
ADC START
CONVERSION
REF
The DDS phase offset is controlled via the DDSPHS MMR. This
MMR contains a 12-bit value that controls the phase of the DDS
output according to the following formula:
Phase Offset =
MUX
2 × π × Phase
212
P0.0/CMPOUT
06020-042
Bit
31:0
This monitor function allows the user to save working registers
to avoid possible data loss due to the low supply or brown-out
conditions. It also ensures that normal code execution does not
resume until a safe supply level has been established.
Figure 46. Comparator
Hysteresis
POWER SUPPLY MONITOR
The power supply monitor on the ADuC7128/ADuC7129
indicates when the IOVDD supply pin drops below one of two
supply trip points. The monitor function is controlled via the
PSMCON register (see Table 56). If enabled in the IRQEN or
FIQEN register, the monitor interrupts the core using the PSMI
bit in the PSMCON MMR. This bit is cleared immediately once
CMP goes high. Note that if the interrupt generated is exited
before CMP goes high (IOVDD is above the trip point), no further
interrupts are generated until CMP returns high. The user should
ensure that code execution remains within the ISR until CMP
returns high.
Figure 47 shows how the input offset voltage and hysteresis
terms are defined. Input offset voltage (VOS) is the difference
between the center of the hysteresis range and the ground level.
This can either be positive or negative. The hysteresis voltage
(VH) is ½ the width of the hysteresis range.
COMPOUT
VH
VOS
VH
COMP0
06020-041
Name
DDSFRQ
Figure 47. Comparator Hysteresis Transfer Function
Table 56. PSMCON MMR Bit Designations
Bit
3
Name
CMP
2
TP
1
PSMEN
0
PSMI
Description
Comparator Bit. This is a read-only bit that directly reflects the state of the comparator.
Read 1 indicates the IOVDD supply is above its selected trip point or the PSM is in power-down mode.
Read 0 indicates the IOVDD supply is below its selected trip point. This bit should be set before leaving
the interrupt service routine.
Trip Point Selection Bit.
0 = 2.79 V
1 = 3.07 V
Power Supply Monitor Enable Bit.
Set to 1 by the user to enable the power supply monitor circuit.
Cleared to 0 by the user to disable the power supply monitor circuit.
Power Supply Monitor Interrupt Bit. This bit is set high by the MicroConverter if CMP is low, indicating low
I/O supply. The PSMI bit can be used to interrupt the processor. Once CMP returns high, the PSMI bit can
be cleared by writing a 1 to this location. A write of 0 has no effect. There is no timeout delay. PSMI can be
cleared immediately once CMP goes high.
Rev. 0 | Page 47 of 92
ADuC7128/ADuC7129
Comparator Interface
The comparator interface consists of a 16-bit MMR, CMPCON, described in Table 57.
Table 57. CMPCON MMR Bit Designations
Bit
15:11
10
Value
Name
CMPEN
9:8
CMPIN
00
01
10
11
7:6
CMPOC
00
01
10
11
5
CMPOL
4:3
CMPRES
00
01
10
11
2
CMPHYST
1
CMPORI
0
CMPOFI
Description
Reserved.
Comparator Enable Bit.
Set by user to enable the comparator.
Cleared by user to disable the comparator.
Note: A comparator interrupt is generated on the enable of the comparator. This should be cleared in the
user software.
Comparator Negative Input Select Bits.
AVDD/2.
ADC3 input.
VREF × 0.6.
Reserved.
Comparator Output Configuration Bits.
IRQ and PLA connections disabled.
IRQ and PLA connections disabled.
PLA connections enabled.
IRQ connections enabled.
Comparator Output Logic State Bit.
When low, the comparator output is high when the positive input (CMP0) is above the negative
input (CMP1).
When high, the comparator output is high when the positive input is below the negative input.
Response Time.
5 μs response time typical for large signals (2.5 V differential).
17 μs response time typical for small signals (0.65 mV differential).
Reserved.
Reserved.
3 μs response time typical for any signal type.
Comparator Hysteresis Bit.
Set by user to have a hysteresis of about 7.5 mV.
Cleared by user to have no hysteresis.
Comparator Output Rising Edge Interrupt.
Set automatically when a rising edge occurs on the monitored voltage (CMP0).
Cleared by user by writing a 1 to this bit.
Comparator Output Falling Edge Interrupt.
Set automatically when a falling edge occurs on the monitored voltage (CMP0).
Cleared by user.
Rev. 0 | Page 48 of 92
ADuC7128/ADuC7129
Example Source Code
OSCILLATOR AND PLL—POWER CONTROL
The ADuC7128/ADuC7129 integrate a 32.768 kHz oscillator,
a clock divider, and a PLL. The PLL locks onto a multiple (1275)
of the internal oscillator to provide a stable 41.78 MHz clock for
the system. The core can operate at this frequency, or at binary
submultiples of it, to allow power saving. The default core clock
is the PLL clock divided by 8 (CD = 3) or 5.2 MHz. The core
clock frequency can be output on the ECLK pin as described in
Figure 48. Note that when the ECLK pin is used to output the
core clock, the output signal is not buffered and is not suitable
for use as a clock source to an external device without an
external buffer.
A power-down mode is available on the ADuC7128/ADuC7129.
The operating mode, clocking mode, and programmable clock
divider are controlled via two MMRs, PLLCON (see Table 61) and
POWCON (see Table 62). PLLCON controls operating mode of
the clock system, and POWCON controls the core clock
frequency and the power-down mode.
WATCHDOG
TIMER
INT. 32kHz1
OSCILLATOR
TCON = 0x480;
while ((T2VAL == t2val_old) || (T2VAL >
3)) //ensures timer value loaded
IRQEN = 0x10;
//enable T2 interrupt
PLLKEY1 = 0xAA;
PLLCON = 0x01;
PLLKEY2 = 0x55;
POWKEY1 = 0x01;
POWCON = 0x27;
// Set Core into Nap mode
POWKEY2 = 0xF4;
In noisy environments, noise can couple to the external crystal
pins, and PLL may lose lock momentarily. A PLL interrupt is
provided in the interrupt controller. The core clock is immediately
halted, and this interrupt is serviced only when the lock is restored.
In case of crystal loss, the watchdog timer should be used. During
initialization, a test on the RSTSTA can determine if the reset
came from the watchdog timer.
XCLKO
CRYSTAL
OSCILLATOR
T2LD = 5;
XCLKI
External Clock Selection
WAKEUP
TIMER
To switch to an external clock on P0.7, configure P0.7 in
Mode 1. The external clock can be up to 44 MHz, providing
the tolerance is 1%.
AT POWER UP
OCLK
32.768kHz
40.78MHz
PLL
P0.7/XCLK
Example Source Code
MDCLK
UCLK
I2C
T2LD = 5;
ANALOG
PERIPHERALS
TCON = 0x480;
CD
CORE
/2CD
while ((T2VAL == t2val_old) || (T2VAL >
3)) //ensures timer value loaded
132.768kHz ±3%
P0.7/ECLK
06020-043
HCLK
Figure 48. Clocking System
IRQEN = 0x10;
//enable T2 interrupt
PLLKEY1 = 0xAA;
PLLCON = 0x03; //Select external clock
PLLKEY2 = 0x55;
External Crystal Selection
To switch to an external crystal, use the following procedure:
1.
2.
3.
4.
Enable the Timer2 interrupt and configure it for a timeout
period of >120 μs.
Follow the write sequence to the PLLCON register, setting
the MDCLK bits to 01 and clearing the OSEL bit.
Force the part into nap mode by following the correct write
sequence to the POWCON register.
When the part is interrupted from nap mode by the Timer2
interrupt source, the clock source has switched to the
external clock.
POWKEY1 = 0x01;
POWCON = 0x27; // Set Core into Nap mode
POWKEY2 = 0xF4;
Power Control System
A choice of operating modes is available on the ADuC7128/
ADuC7129. Table 58 describes what part of the ADuC7128/
ADuC7129 is powered on in the different modes and indicates
the power-up time. Table 59 gives some typical values of the total
current consumption (analog + digital supply currents) in the
different modes, depending on the clock divider bits. The ADC is
turned off.
Note that these values also include current consumption of the
regulator and other parts on the test board on which these values
were measured.
Rev. 0 | Page 49 of 92
ADuC7128/ADuC7129
Table 58. Operating Modes
Mode
Active
Pause
Nap
Sleep
Stop
Core
On
Peripherals
On
On
PLL
On
On
On
XTAL/T2/T3
On
On
On
On
XIRQ
On
On
On
On
On
Start-Up/Power-On Time
130 ms at CD = 0
24 ns at CD = 0; 3.06 μs at CD = 7
24 ns at CD = 0; 3.06 μs at CD = 7
1.58 ms
1.7 ms
Table 59. Typical Current Consumption at 25°C
PC[2:0]
000
001
010
011
100
Mode
Active
Pause
Nap
Sleep
Stop
CD = 0
33.1
22.7
3.8
0.4
0.4
CD = 1
21.2
13.3
3.8
0.4
0.4
CD = 2
13.8
8.5
3.8
0.4
0.4
MMRs and Keys
CD = 3
10
6.1
3.8
0.4
0.4
CD = 4
8.1
4.9
3.8
0.4
0.4
Bit
7:6
5
Value
Name
OSEL
PLLKEYx Register
Address
0xFFFF0410
0xFFFF0418
Default Value
0x0000
0x0000
Access
W
W
4:2
1:0
PLLCON Register
Name
PLLCON
Address
0xFFFF0414
Default Value
0x21
Access
R/W
Address
0xFFFF0404
0xFFFF040C
Default Value
0x0000
0x0000
Access
W
W
POWCON Register
Name
POWCON
Address
0xFFFF0408
Default Value
0x0003
MDCLK
00
01
10
11
POWKEYx Register
Name
POWKEY1
POWKEY2
CD = 7
6.45
3.85
3.8
0.4
0.4
Bit
7
6:4
Value
Name
PC
000
001
010
011
Access
R/W
POWCON
POWKEY1 = 0x01
POWCON = user value
POWKEY2 = 0xF4
Description
Reserved.
32 kHz PLL Input Selection.
Set by user to use the internal
32 kHz oscillator.
Set by default.
Cleared by user to use the
external 32 kHz crystal.
Reserved.
Clocking Modes.
Reserved.
PLL. Default configuration.
Reserved.
External clock on P0.7 pin.
Table 62. POWCON MMR Bit Designations
Table 60. PLLCON and POWCON Write Sequence
PLLCON
PLLKEY1 = 0xAA
PLLCON = 0x01
PLLKEY2 = 0x55
CD = 6
6.7
4
3.8
0.4
0.4
Table 61. PLLCON MMR Bit Designations
To prevent accidental programming, a certain sequence must be
followed when writing in the PLLCON and POWCON registers
(see Table 60).
Name
PLLKEY1
PLLKEY2
CD = 5
7.2
4.3
3.8
0.4
0.4
100
Others
3
2:0
RSVD
CD
000
001
010
011
100
101
110
111
Rev. 0 | Page 50 of 92
Description
Reserved.
Operating Modes.
Active mode.
Pause mode.
Nap.
Sleep mode. IRQ0 to IRQ3 and Timer2
can wake up the
ADuC7128/ADuC7129.
Stop mode.
Reserved.
Reserved.
CPU Clock Divider Bits.
41.779200 MHz.
20.889600 MHz.
10.444800 MHz.
5.222400 MHz.
2.611200 MHz.
1.305600 MHz.
654.800 kHz.
326.400 kHz.
ADuC7128/ADuC7129
DIGITAL PERIPHERALS
PWM GENERAL OVERVIEW
HIGH SIDE
(PWM1)
The ADuC7128/ADuC7129 integrate a six channel PWM interface. The PWM outputs can be configured to drive an H-bridge
or can be used as standard PWM outputs. On power up, the PWM
outputs default to H-bridge mode. This ensures that the motor
is turned off by default. In standard PWM mode, the outputs
are arranged as three pairs of PWM pins. Users have control
over the period of each pair of outputs and over the duty cycle
of each individual output.
LOW SIDE
(PWM2)
PWM1COM3
PWM1COM2
Name
PWMCON1
PWM1COM1
PWM1COM2
PWM1COM3
PWM1LEN
PWM2COM1
PWM2COM2
PWM2COM3
PWM2LEN
PWM3COM1
PWM3COM2
PWM3COM3
PWM3LEN
PWMCON2
PWMICLR
Description
PWM Control
Compare Register 1 for PWM Outputs 1 and 2
Compare Register 2 for PWM Outputs 1 and 2
Compare Register 3 for PWM Outputs 1 and 2
Frequency Control for PWM Outputs 1 and 2
Compare Register 1 for PWM Outputs 3 and 4
Compare Register 2 for PWM Outputs 3 and 4
Compare Register 3 for PWM Outputs 3 and 4
Frequency Control for PWM Outputs 3 and 4
Compare Register 1 for PWM Outputs 5 and 6
Compare Register 2 for PWM Outputs 5 and 6
Compare Register 3 for PWM Outputs 5 and 6
Frequency Control for PWM Outputs 5 and 6
PWM Convert Start Control
PWM Interrupt Clear
06020-044
PWM1COM1
Table 63. PWM MMRs
PWM1LEN
Figure 49. PWM Timing
The PWM clock is selectable via PWMCON1 with one of the
following values: UCLK/2, 4, 8, 16, 32, 64, 128, or 256. The
length of a PWM period is defined by PWMxLEN.
The PWM waveforms are set by the count value of the 16-bit
timer and the compare registers contents as shown with the
PWM1 and PWM2 waveforms above.
The low-side waveform, PWM2, goes high when the timer
count reaches PWM1LEN, and it goes low when the timer
count reaches the value held in PWM1COM3 or when the
high-side waveform PWM1 goes low.
The high-side waveform, PWM1, goes high when the timer
count reaches the value held in PWM1COM1, and it goes low
when the timer count reaches the value held in PWM1COM2.
In all modes, the PWMxCOMx MMRs controls the point at
which the PWM outputs change state. An example of the first pair
of PWM outputs (PWM1 and PWM2) is shown in Figure 49.
Table 64. PWMCON1 MMR Bit Designations
Bit
14
Name
SYNC
13
PWM6INV
12
PWM4NV
11
PWM2INV
10
PWMTRIP
9
ENA
8
7
PWMCP2
PWMCP1
Description
Enables PWM Synchronization.
Set to 1 by the user so that all PWM counters are reset on the next clock edge after the detection of a high-to-low
transition on the SYNC pin.
Cleared by user to ignore transitions on the SYNC pin.
Set to 1 by the user to invert PWM6.
Cleared by user to use PWM6 in normal mode.
Set to 1 by the user to invert PWM4.
Cleared by user to use PWM4 in normal mode.
Set to 1 by the user to invert PWM2.
Cleared by user to use PWM2 in normal mode.
Set to 1 by the user to enable PWM trip interrupt. When the PWMTRIP input is low, the PWMEN bit is cleared and an
interrupt is generated.
Cleared by user to disable the PWMTRIP interrupt.
If HOFF = 0 and HMODE = 1.
Set to 1 by the user to enable PWM outputs.
Cleared by user to disable PWM outputs.
If HOFF = 1 and HMODE = 1, see Table 65.
If not in H-Bridge mode, this bit has no effect.
PWM Clock Prescaler Bits.
Sets UCLK divider.
Rev. 0 | Page 51 of 92
ADuC7128/ADuC7129
Bit
6
Name
PWMCP0
5
POINV
4
HOFF
3
LCOMP
2
DIR
1
HMODE
0
PWMEN
Description
2.
4.
8.
16.
32.
64.
128.
256.
Set to 1 by the user to invert all PWM outputs.
Cleared by user to use PWM outputs as normal.
High Side Off.
Set to 1 by the user to force PWM1 and PWM3 outputs high. This also forces PWM2 and PWM4 low.
Cleared by user to use the PWM outputs as normal.
Load Compare Registers.
Set to 1 by the user to load the internal compare registers with the values in PWMxCOMx on the next transition of the
PWM timer from 0x00 to 0x01.
Cleared by user to use the values previously stored in the internal compare registers.
Direction Control.
Set to 1 by the user to enable PWM1 and PWM2 as the output signals while PWM3 and PWM4 are held low.
Cleared by user to enable PWM3 and PWM4 as the output signals while PWM1 and PWM2 are held low.
Enables H-bridge mode.
Set to 1 by the user to enable H-Bridge mode and Bit 1 to Bit 5 of PWMCON1.
Cleared by user to operate the PWMs in standard mode.
Set to 1 by the user to enable all PWM outputs.
Cleared by user to disable all PWM outputs.
In H-bridge mode, HMODE = 1. See Table 65 to determine the PWM outputs.
Table 65. PWM Output Selection
PWMCOM1 MMR
ENA HOFF POINV
0
0
x
x
1
x
1
0
0
1
0
0
1
0
1
1
0
1
1
DIR
x
x
0
1
0
1
PWM1
1
1
0
HS1
HS1
1
PWM Outputs
PWM2 PWMR3
1
1
0
1
0
HS1
1
LS
0
LS1
1
1
HS1
PWM4
1
0
LS1
0
1
LS1
HS = high side, LS = low side.
The PWM trip interrupt can be cleared by writing any value to
the PWMICLR MMR. Note that when using the PWM trip
interrupt, the PWM interrupt should be cleared before exiting
the ISR. This prevents generation of multiple interrupts.
PWM CONVERT START CONTROL
The PWM can be configured to generate an ADC convert start
signal after the active low side signal goes high. There is a programmable delay between when the low-side signal goes high and
the convert start signal is generated.
This is controlled via the PWMCON2 MMR. If the delay
selected is higher than the width of the PWM pulse, the
interrupt remains low.
On power-up, PWMCON1 defaults to 0x12 (HOFF = 1 and
HMODE = 1). All GPIO pins associated with the PWM are
configured in PWM mode by default (see Table 66).
Table 66. Compare Register
Name
PWM1COM1
PWM1COM2
PWM1COM3
PWM2COM1
PWM2COM2
PWM2COM3
PWM3COM1
PWM3COM2
PWM3COM3
Address
0xFFFF0F84
0xFFFF0F88
0xFFFF0F8C
0xFFFF0F94
0xFFFF0F98
0xFFFF0F9C
0xFFFF0FA4
0xFFFF0FA8
0xFFFF0FAC
Default Value
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 0 | Page 52 of 92
ADuC7128/ADuC7129
Table 67. PWMCON2 MMR Bit Designations
Quadrature Encoder
Bit
7
A quadrature encoder is used to determine both the speed and
direction of a rotating shaft. In its most common form, there are
two digital outputs, S1 and S2. As the shaft rotates, both S1 and
S2 toggle; however, they are 90° out of phase. The leading output
determines the direction of rotation. The time between each
transition indicates the speed of rotation.
6:4
RSVD
3:0
CSD3
Description
Set to 1 by the user to enable the PWM
to generate a convert start signal.
Cleared by user to disable the PWM
convert start signal.
Reserved. This bit should be set to 0 by
the user.
Convert Start Delay. Delays the convert
start signal by a number of clock pulses.
S1
01
CSD2
CSD1
CSD0
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
S2
00
11
10
00
01
4 clock pulses.
8 clock pulses.
12 clock pulses.
16 clock pulses.
20 clock pulses.
24 clock pulses.
28 clock pulses.
32 clock pulses.
36 clock pulses.
40 clock pulses.
44 clock pulses.
48 clock pulses.
52 clock pulses.
56 clock pulses.
60 clock pulses.
64 clock pulses.
CLOCKWISE
11
COUNTER CLOCKWISE
10
00
01
11
10
00
Figure 51. Quadrate Encoder Input Values
The quadrature encoder takes the incremental input shown in
Figure 51 and increments or decrements a counter depending
on the direction and speed of the rotating shaft.
On the ADuC7128/ADuC7129, the internal counter is clocked
on the rising edge of the S1 input, and the S2 input indicates the
direction of rotation/count. The counter increments when S2
is high and decrements when it is low.
When calculating the time from the convert start delay to the
start of an ADC conversion, the user needs to take account of
internal delays. The example below shows the case for a delay of
four clocks. One additional clock is required to pass the convert
start signal to the ADC logic. Once the ADC logic receives the
convert start signal an ADC conversion begins on the next
ADC clock edge (see Figure 50).
In addition, if the software has prior knowledge of the direction
of rotation, one input can be ignored (S2) and the other can act
as a clock (S1).
For additional flexibility, all inputs can be internally inverted
prior to use.
The quadrature encoder operates asynchronously from the
system clock.
Input Filtering
UCLOCK
Filtering can be applied to the S1 input by setting the FILTEN
bit in QENCON. S1 normally acts as the clock to the counter;
however, the filter can be used to ignore positive edges on S1
unless there has been a high or a low pulse on S2 between two
positive edges on S1 (see Figure 52).
LOW SIDE
COUNT
PWM SIGNAL
TO CONVST
06020-045
S1
SIGNAL PASSED
TO ADC LOGIC
Figure 50. ADC Conversion
S2 HIGH PULSE
06020-047
Name
CSEN
06020-046
Value
S2 LOW PULSE
Figure 52. S1 Input Filtering
Rev. 0 | Page 53 of 92
ADuC7128/ADuC7129
Table 68. QENCON MMR Bit Designations
Bit
15:11
10
Name
RSVD
FILTEN
9
8
RSVD
S2INV
7
S1INV
6
DIRCON
5
S1IRQEN
4
3
RSVD
UIRQEN
2
OIREQEN
1
0
RSVD
ENQEN
Description
Reserved.
Set to 1 by the user to enable filtering on the S1 pin.
Cleared by user to disable filtering on the S1 pin.
Reserved. This bit should be set to 0 by the user.
Set to 1 by the user to invert the S2 input.
Cleared by user to use the S2 input as normal.
If the DIRCON bit is set, then S2INV controls the direction of the counter.
In this case, set to 1 by the user to operate the counter in increment mode.
Cleared by user to operate the counter in decrement mode.
Set to 1 by the user to invert the S1 input.
Cleared by user to use the S1 input as normal.
Direction Control.
Set to 1 by the user to enable S1 as the input to the counter clock. The direction of the counter is controlled
via the S2INV bit.
Cleared by user to operate in normal mode.
Set to 1 by the user to generate an IRQ when a low-to-high transition is detected on S1.
Cleared by the user to disable the interrupt.
This bit should be set to 0 by the user.
Underflow IRQ Enable.
Set to 1 by the user to generate an interrupt if QENVAL underflows.
Cleared by the user to disable the interrupt.
Overflow IRQ Enable.
Set to 1 by the user to generate an interrupt if QENVAL overflows.
Cleared by user to disable the interrupt.
This bit should be set to 0 by the user.
Quadrature Encoder Enable.
Set to 1 by the user to enable the quadrature encoder.
Cleared by user to disable the quadrature encoder.
Table 69. QENSTA MMR Bit Designations
Bit
7:5
4
Name
RSVD
S1EDGE
3
2
RSVD
UNDER
1
OVER
0
DIR
Description
Reserved.
S1 Rising Edge.
This bit is set automatically on a rising edge of S1.
Cleared by reading QENSTA.
Reserved.
Underflow Flag.
This bit is set automatically if an underflow occurs.
Cleared by reading QENSTA.
This bit is set automatically if an overflow has occurred.
Cleared by reading QENSTA.
Direction of the Counter.
Set to 1 by hardware to indicate that the counter is incrementing.
Set to 0 by hardware to indicate that the counter is decrementing.
QENVAL Register
QENDAT Register
Name
QENDAT
Address
0xFFFF0F08
Default Value
0Xffff
Access
R/W
The QENDAT register holds the maximum value allowed for the
QENVAL register. If the QENVAL register increments past the
value in this register, an overflow condition occurs. When an overflow occurs, the QENVAL register is reset to 0x0000. When the
QENVAL register decrements past zero during an underflow,
it is loaded with the value in QENDAT.
Name
QENVAL
Address
0xFFFF0F0C
Default Value
0x0000
Access
R/W
The QENVAL register contains the current value of the quadrature
encoder counter.
Rev. 0 | Page 54 of 92
ADuC7128/ADuC7129
QENCLR Register
Name
QENCLR
Address
0xFFFF0F14
GENERAL-PURPOSE I/O
Default Value
0x00000000
Access
R/W
Writing any value to the QENCLR register clears the QENVAL
register to 0x0000. The bits in this register are undefined.
QENSET Register
Name
QENSET
Address
0xFFFF0F18
Default Value
0x00000000
Access
R/W
Writing any value to the QENSET register loads the QENVAL
register with the value in QENDAT. The bits in this register are
undefined.
Note that the interrupt conditions are OR’ed together to form
one interrupt to the interrupt controller. The interrupt service
routine should check the QENSTA register to find out the cause
of the interrupt.
•
•
•
The S1 and S2 inputs appear as the QENS1 and QENS2
inputs in the GPIO list.
The motor speed can be measured by using the capture
facility in Timer0 or Timer1.
An overflow of either timer can be checked by using an ISR
or by checking IRQSIG.
The counter with the quadrature encoder is gray encoded to
ensure reliable data transfer across clock boundaries. When an
underflow or overflow occur, the count value does not jump to
the other end of the scale; instead, the direction of count changes.
When this happens, the value in QENDAT is subtracted from the
value derived from the gray count.
When the value in QENDAT changes, the value read back from
QENVAL changes. However, the gray encoded value does not
change. This only occurs after an underflow or overflow. If the
value in QENDAT changes, there must be a write to QENSET
or QENCLR to ensure a valid number is read back from QENVAL.
The ADuC7128/ADuC7129 provide 40 general-purpose,
bidirectional I/O (GPIO) pins. All I/O pins are 5 V tolerant,
meaning that the GPIOs support an input voltage of 5 V. In
general, many of the GPIO pins have multiple functions (see
Table 70). By default, the GPIO pins are configured in GPIO mode.
All GPIO pins have an internal pull-up resistor (of about 100 kΩ)
and their drive capability is 1.6 mA. Note that a maximum of
20 GPIO can drive 1.6 mA at the same time. The following GPIOs
have programmable pull-up: P0.0, P0.4, P0.5, P0.6, P0.7, and
the eight GPIOs of P1.
The 40 GPIOs are grouped in five ports: Port 0 to Port 4. Each
port is controlled by four or five MMRs, with x representing the
port number.
GPxCON Register
Name
GP0CON
GP1CON
GP2CON
GP3CON
GP4CON
Address
0xFFFF0D00
0xFFFF0D04
0xFFFF0D08
0xFFFF0D0C
0xFFFF0D10
Default Value
0x00000000
0x00000000
0x00000000
0x11111111
0x00000000
Access
R/W
R/W
R/W
R/W
R/W
Note that the kernel changes P0.6 from its default configuration
at reset (MRST) to GPIO mode. If MRST is used for external
circuitry, an external pull-up resistor should be used to ensure
that the level on P0.6 does not drop when the kernel switches
mode. Otherwise, P0.6 goes low for the reset period. For example,
if MRST is required for power-down, it can be reconfigured in
GP0CON MMR.
The input level of any GPIO can be read at any time in the
GPxDAT MMR, even when the pin is configured in a mode
other than GPIO. The PLA input is always active.
When the ADuC7128/ADuC7129 enter a power-saving mode,
the GPIO pins retain their state.
GPxCON is the Port x control register, and it selects the
function of each pin of Port x, as described in Table 70.
Rev. 0 | Page 55 of 92
ADuC7128/ADuC7129
Table 70. GPIO Pin Function Designations
Port
0
1
2
3
4
1
2
Pin
P0.0
P0.11
P0.21
P0.3
P0.4
P0.5
P0.6
P0.7
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P2.0
P2.11
P2.21
P2.31
P2.41
P2.51
P2.61
P2.71
P3.0
P3.1
P3.2
P3.3
P3.4
P3.5
P3.61
P3.71
P4.0
P4.1
P4.2
P4.3
00
GPIO
GPIO
GPIO
GPIO
GPIO/IRQ0
GPIO/IRQ1
GPIO/T1
GPIO
GPIO/T1
GPIO
GPIO
GPIO
GPIO/IRQ2
GPIO/IRQ3
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
P4.4
P4.5
P4.6
P4.7
GPIO
GPIO
GPIO
GPIO
Configuration
01
10
CMP
MS0
BLE
BHE
A16
TRST
MS1
CONVST
ADCBUSY
PLM_COMP
AE
MRST
ECLK/XCLK2 SIN0
SIN0
SCL0
SOUT0
SDA0
RTS0
SCL1
CTS0
SDA1
RI0
CLK
DCD0
MISO
DSR0
MOSI
DTR0
CSL
SYNC
SOUT
WS
RTS1
RS
CTS1
AE
RI1
MS0
DCD1
MS1
DSR1
MS2
DTR1
MS3
PWM1
AD0
PWM2
AD1
PWM3
AD2
PWM4
AD3
PWM5
AD4
PWM6
AD5
PWM1
AD6
PWM3
AD7
QENS1
AD8
QENS2
AD9
RSVD
AD10
AD11
Trip
(Shutdown)
PLMIN
AD12
PLMOUT
AD13
SIN1
AD14
SOUT1
AD15
P
Table 71. GPxCON MMR Bit Designations
11
PLAI[7]
ADCBUSY
PLAO[1]
PLAO[2]
PLAO[3]
PLAO[4]
PLAI[0]
PLAI[1]
PLAI[2]
PLAI[3]
PLAI[4]
PLAI[5]
PLAI[6]
PLAO[0]
PLAO[5]
PLAO[6]
PLAO[7]
B
B
PLAI[8]
PLAI[9]
PLAI[10]
PLAI[11]
PLAI[12]
PLAI[13]
PLAI[14]
PLAI[15]
PLAO[8]
PLAO[9]
PLAO[10]
PLAO[11]
PLAO[12]
PLAO[13]
PLAO[14]
PLAO[15]
Available only on the 80-lead ADuC7129.
When configured in Mode 1, PO.7 is ECLK by default, or core clock output. To
configure it as a clock ouput, the MDCLK bits in PLLCON must be set to 11.
Bit
31:30
29:28
27:26
25:24
23:22
21:20
19:18
17:16
15:14
13:12
11:10
9:8
7:6
5:4
3:2
1:0
Description
Reserved
Select function of Px.7 pin
Reserved
Select function of Px.6 pin
Reserved
Select function of Px.5 pin
Reserved
Select function of Px.4 pin
Reserved
Select function of Px.3 pin
Reserved
Select function of Px.2 pin
Reserved
Select function of Px.1 pin
Reserved
Select function of Px.0 pin
GPxPAR Register
Name
GP0PAR
GP1PAR
GP3PAR
GP4PAR
Address
0xFFFF0D2C
0xFFFF0D3C
0xFFFF0D5C
0xFFFF0D6C
Default Value
0x20000000
0x00000000
0x00222222
0x00000000
Access
R/W
R/W
R/W
R/W
GPxPAR programs the parameters for Port 0, Port 1, Port 3, and
Port 4. Note that the GPxDAT MMR must always be written
after changing the GPxPAR MMR.
Table 72. GPxPAR MMR Bit Designations
Bit
31:29
28
27:25
24
23:21
20
19:17
16
15:13
12
11:9
8
7:5
4
3:1
0
Rev. 0 | Page 56 of 92
Description
Reserved
Pull-up disable Px.7 pin
Reserved
Pull-up disable Px.6 pin
Reserved
Pull-up disable Px.5 pin
Reserved
Pull-up disable Px.4 pin
Reserved
Pull-up disable Px.3 pin
Reserved
Pull-up disable Px.2 pin
Reserved
Pull-up disable Px.1 pin
Reserved
Pull-up disable Px.0 pin
ADuC7128/ADuC7129
GPxDAT Register
Name
GP0DAT
GP1DAT
GP2DAT
GP3DAT
GP4DAT
Address
0xFFFF0D20
0xFFFF0D30
0xFFFF0D40
0xFFFF0D50
0xFFFF0D60
SERIAL PORT MUX
Default Value
0x000000XX
0x000000XX
0x000000XX
0x000000XX
0x000000XX
Access
R/W
R/W
R/W
R/W
R/W
GPxDAT is a Port x configuration and data register. It configures
the direction of the GPIO pins of Port x, sets the output value
for the pins configured as output, and receives and stores the
input value of the pins configured as input.
Table 73. GPxDAT MMR Bit Designations
Bit
31:24
23:16
15:8
7:0
Description
Direction of the Data.
Set to 1 by user to configure the GPIO pins as outputs.
Cleared to 0 by user to configure the GPIO pins as
inputs.
Port x Data Output.
Reflect the state of Port x pins at reset (read only).
Port x Data Input (Read Only).
The serial port mux multiplexes the serial port peripherals (two
I2Cs, an SPI, and two UARTs) and the programmable logic array
(PLA) to a set of 10 GPIO pins. Each pin must be configured to
its specific I/O function as described in Table 76.
Table 76. SPM Configuration
Pin
SPM0
GPIO
(00)
UART
(01)
UART/I2C/SPI
(10)
PLA
(11)
P1.0
SIN0
I2C0SCL
PLAI[0]
SPM1
P1.1
SOUT0
I2C0SDA
PLAI[1]
SPM2
P1.2
RTS0
I2C1SCL
PLAI[2]
SPM3
P1.3
CTS0
I2C1SDA
PLAI[3]
SPM4
P1.4
RI0
SPICLK
PLAI[4]
SPM5
P1.5
DCD0
SPIMISO
PLAI[5]
SPM6
P1.6
DSR0
SPIMOSI
PLAI[6]
SPM7
P1.7
DTR0
SPICSL
PLAO[0]
SPM8
P0.7
ECLK
SIN0
PLAO[4]
1
SPM9
P2.0
PWMSYNC
SOUT0
PLAO[5]
SPM10
P2.21
RTS1
RS
PLAO[7]
SPM11
P2.31
CTS1
AE
SPM12
P2.41
RI1
MS0
SPM13
P2.51
DCD1
MS1
SPM14
P2.61
DSR1
MS2
SPM15
P2.71
DTR1
MS3
SPM16
P4.6
SIN1
AD14
PLAO[14]
GPxSET is a data set Port x register.
SPM17
P4.7
SOUT1
AD15
PLAO[15]
Table 74. GPxSET MMR Bit Designations
1
GPxSET Register
Name
GP0SET
GP1SET
GP2SET
GP3SET
GP4SET
Bit
31:24
23:16
15:0
Address
0xFFFF0D24
0xFFFF0D34
0xFFFF0D44
0xFFFF0D54
0xFFFF0D64
Default Value
0x000000XX
0x000000XX
0x000000XX
0x000000XX
0x000000XX
Access
W
W
W
W
W
Description
Reserved.
Data Port x Set Bit.
Set to 1 by user to set bit on Port x; also sets the
corresponding bit in the GPxDAT MMR.
Cleared to 0 by user; does not affect the data out.
Reserved.
Table 76 details the mode for each of the SPMUX GPIO pins.
This configuration has to be performed via the GP0CON,
GP1CON and GP2CON MMRs. By default these pins are
configured as GPIOs.
UART SERIAL INTERFACE
GPxCLR Register
Name
GP0CLR
GP1CLR
GP2CLR
GP3CLR
GP4CLR
Address
0xFFFF0D28
0xFFFF0D38
0xFFFF0D48
0xFFFF0D58
0xFFFF0D68
Default Value
0x000000XX
0x000000XX
0x000000XX
0x000000XX
0x000000XX
Access
W
W
W
W
W
GPxCLR is a data clear Port x register.
Table 75. GPxCLR MMR Bit Designations
Bit
31:24
23:16
15:0
Available only on the 80-lead ADuC7129.
Description
Reserved.
Data Port x Clear Bit.
Set to 1 by user to clear bit on Port x; also clears
the corresponding bit in the GPxDAT MMR.
Cleared to 0 by user; does not affect the data out.
Reserved.
The ADuC7128/ADuC7129 contain two identical UART
blocks. Although only UART0 is described here, UART1
functions in exactly the same way.
The UART peripheral is a full-duplex universal asynchronous
receiver/transmitter, fully compatible with the 16450 serial port
standard.
The UART performs serial-to-parallel conversion on data
characters received from a peripheral device or a modem, and
parallel-to-serial conversion on data characters received from
the CPU. The UART includes a fractional divider for baud rate
generation and has a network-addressable mode. The UART
function is made available on 10 pins of the ADuC7128/
ADuC7129 (see Table 77).
Rev. 0 | Page 57 of 92
ADuC7128/ADuC7129
Calculation of the baud rate using fractional divider is as
follows:
Table 77. UART Signal Descriptions
Pin
SPM0 (Mode 1)
SPM1 (Mode 1)
SPM2 (Mode 1)
SPM3 (Mode 1)
SPM4 (Mode 1)
SPM5 (Mode 1)
SPM6 (Mode 1)
SPM7 (Mode 1)
SPM8 (Mode 2)
SPM9 (Mode 2)
Signal
SIN0
SOUT0
RTS0
CTS0
RI0
DCD0
DSR0
DTR0
SIN0
SOUT0
Description
Serial Receive Data.
Serial Transmit Data.
Request to Send.
Clear to Send.
Ring Indicator.
Data Carrier Detect.
Data Set Ready.
Data Terminal Ready.
Serial Receive Data.
Serial Transmit Data.
41.78 MHz
Baud Rate =
CD
2
M+
× 16 × DL × 2 × ( M +
41.78 MHz
N
=
2048 Baud Rate × 2CD × 16 × DL × 2
For example, generation of 19,200 bauds with CD bits = 3.
Table 78 gives DL = 0x08.
The serial communication adopts an asynchronous protocol
that supports various word-length, stop-bits, and parity
generation options selectable in the configuration register.
Baud Rate Generation
There are two ways of generating the UART baud rate: normal
450 UART baud rate generation and using the fractional divider.
M+
41.78 MHz
N
=
2048 19200 × 2 3 × 16 × 8 × 2
M+
N
= 1.06
2048
where:
M=1
N = 0.06 × 2048 = 128
Baud Rate =
Normal 450 UART Baud Rate Generation
41.78 MHz
128
2 × 16 × 8 × 2 ×
2048
(
3
The baud rate is a divided version of the core clock, using the
value in COM0DIV0 and COM0DIV1 MMRs (16-bit value, DL).
Baud Rate =
41.78 MHz
2 CD × 16 × 2 × DL
Table 78 gives some common baud rate values.
CD
0
0
0
3
3
3
DL
0x88
0x44
0x0B
0x11
0x08
0x01
Actual Baud Rate
9600
19,200
118,691
9600
20,400
163,200
% Error
0%
0%
3%
0%
6.25%
41.67%
Using the Fractional Divider
where:
Baud Rate = 19,200 bps.
Error = 0% compared to 6.25% with the normal baud rate
generator.
The UART interface consists of 12 registers.
Table 79. UART MMRs
Register
Description
COMxTX
COMxRX
COMxDIV0
COMxTX, COMxRX,
and COMxDIV0
8-Bit Transmit Register.
8-Bit Receive Register.
Divisor Latch (Low Byte).
Share The Same Address Location.
COMxTX and COMxRX can be
accessed when Bit 7 in COMxCON0
register is cleared. COMxDIV0 can
be accessed when Bit 7 of
COMxCON0 is set.
Divisor Latch (High Byte).
Line Control Register.
Line Status Register.
Interrupt Enable Register.
Interrupt Identification Register.
Modem Control Register.
Modem Status Register.
16-Bit Fractional Baud Divide Register.
8-Bit Scratch Register Used for
Temporary Storage. Also used in
network addressable UART mode.
The fractional divider combined with the normal baud rate
generator allows the generating of a wider range of more
accurate baud rates.
/2
FBEN
/16DL
UART
/(M + N/2048)
Figure 53. Baud Rate Generation Options
06020-048
CORE
CLOCK
)
UART Register Definitions
Table 78. Baud Rate Using the Normal Baud Rate Generator
Baud Rate
9600
19,200
115,200
9600
19,200
115,200
N
)
2048
COMxDIV1
COMxCON0
COMxSTA0
COMxIEN0
COMxIID0
COMxCON1
COMxSTA1
COMxDIV2
COMxSCR
Rev. 0 | Page 58 of 92
ADuC7128/ADuC7129
Table 80. COMxCON0 MMR Bit Designations
Bit
7
Value
Name
DLAB
6
BRK
5
SP
4
EPS
3
PEN
2
STOP
1:0
WLS
00
01
10
11
Description
Divisor Latch Access.
Set by user to enable access to COMxDIV0 and COMxDIV1 registers.
Cleared by user to disable access to COMxDIV0 and COMxDIV1 and enable access to COMxRX and COMxTX.
Set Break.
Set by user to force SOUT to 0.
Cleared to operate in normal mode.
Stick Parity.
Set by user to force parity to defined values.
1 if EPS = 1 and PEN = 1
0 if EPS = 0 and PEN = 1
Even Parity Select Bit.
Set for even parity.
Cleared for odd parity.
Parity Enable Bit.
Set by user to transmit and check the parity bit.
Cleared by user for no parity transmission or checking.
Stop Bit.
Set by user to transmit 1.5 stop bits if the word length is 5 bits or 2 stop bits if the word length is 6 bits, 7 bits, or
8 bits. The receiver checks the first stop bit only, regardless of the number of stop bits selected.
Cleared by user to generate 1 stop bit in the transmitted data.
Word Length Select.
5 bits.
6 bits.
7 bits.
8 bits.
Table 81. COMxSTA0 MMR Bit Designations
Bit
7
6
Name
RSVD
TEMT
5
THRE
4
BI
3
FE
2
PE
1
OE
0
DR
Description
Reserved.
COMxTX Empty Status Bit.
Set automatically if COMxTX is empty.
Cleared automatically when writing to COMxTX.
COMxTX and COMxRX Empty.
Set automatically if COMxTX and COMxRX are empty.
Cleared automatically when one of the registers receives data.
Break Error.
Set when SIN is held low for more than the maximum word length.
Cleared automatically.
Framing Error.
Set when stop bit invalid.
Cleared automatically.
Parity Error.
Set when a parity error occurs.
Cleared automatically.
Overrun Error.
Set automatically if data is overwritten before it is read.
Cleared automatically.
Data Ready.
Set automatically when COMxRX is full.
Cleared by reading COMxRX.
Rev. 0 | Page 59 of 92
ADuC7128/ADuC7129
Table 82. COMxIEN0 MMR Bit Designations
Bit
7:4
3
Name
RSVD
EDSSI
2
ELSI
1
ETBEI
0
ERBFI
Description
Reserved.
Modem Status Interrupt Enable Bit.
Set by user to enable generation of an interrupt if any of COMxSTA1[3:0] are set.
Cleared by user.
RX Status Interrupt Enable Bit.
Set by user to enable generation of an interrupt if any of COMxSTA0[3:1] are set.
Cleared by user.
Enable Transmit Buffer Empty Interrupt.
Set by user to enable interrupt when buffer is empty during a transmission.
Cleared by user.
Enable Receive Buffer Full Interrupt.
Set by user to enable interrupt when buffer is full during a reception.
Cleared by user.
Table 83. COMxIID0 MMR Bit Designations
Bit 2:1
Status Bits
00
11
10
01
00
Bit 0
NINT
1
0
0
0
0
Priority
1
2
3
4
Definition
No Interrupt.
Receive Line Status Interrupt.
Receive Buffer Full Interrupt.
Transmit Buffer Empty Interrupt.
Modem Status Interrupt.
Clearing Operation
Read COMxSTA0.
Read COMxRX.
Write data to COMxTX or read COMxIID0.
Read COMxSTA1.
Table 84. COMxCON1 MMR Bit Designations
Bit
7:5
4
Name
RSVD
LOOPBACK
3
2
1
RTS
0
DTR
Description
Reserved.
Loop Back.
Set by user to enable loop-back mode. In loop-back mode, the SOUT is forced high. In addition, the modem
signals are directly connected to the status inputs (RTS to CTS, DTR to DSR, OUT1 to RI, and OUT2 to DCD).
Reserved.
Reserved.
Request to Send.
Set by user to force the RTS output to 0.
Cleared by user to force the RTS output to 1.
Data Terminal Ready.
Set by user to force the DTR output to 0.
Cleared by user to force the DTR output to 1.
Rev. 0 | Page 60 of 92
ADuC7128/ADuC7129
Table 85. COMxSTA1 MMR Bit Designations
Bit
7
6
5
4
3
Name
DCD
RI
DSR
CTS
DDCD
2
TERI
1
DDSR
0
DCTS
Description
Data Carrier Detect.
Ring Indicator.
Data Set Ready.
Clear to Send.
Delta Data Carrier Detect.
Set automatically if DCD changed state since COMxSTA1 last read.
Cleared automatically by reading COMxSTA1.
Trailing Edge Ring Indicator.
Set if NRI changed from 0 to 1 since COMxSTA1 last read.
Cleared automatically by reading COMxSTA1.
Delta Data Set Ready.
Set automatically if DSR changed state since COMxSTA1 last read.
Cleared automatically by reading COMxSTA1.
Delta Clear to Send.
Set automatically if CTS changed state since COMxSTA1 last read.
Cleared automatically by reading COMxSTA1.
Table 86. COMxDIV2 MMR Bit Designations
Bit
15
Name
FBEN
14:13
12:11
10:0
RSVD
FBM[1 to 0]
FBN[10 to 0]
Description
Fractional Baud Rate Generator Enable Bit.
Set by user to enable the fractional baud rate generator.
Cleared by user to generate baud rate using the standard 450 UART baud rate generator.
Reserved.
M, if FBM = 0, M = 4 (see the Using the Fractional Divider section).
N (see the Using the Fractional Divider section).
Network Addressable UART Mode
Network Addressable UART Register Definitions
This mode allows connecting the MicroConverter on a 256-node
serial network, either as a hardware single master or via software
in a multimaster network. Bit 7 of COMxIEN1 (ENAM bit)
must be set to enable UART in network-addressable mode.
Four additional registers, COMxIEN0, COMxIEN1, COMxIID1,
and COMxADR are used only in network addressable UART
mode.
Note that there is no parity check in this mode. The parity bit is
used for address.
COM0IEN1
= 0xE7;
COM0TX = 0xA0;
In network address mode, the least significant bit of the
COMxIEN1 register is the transmitted network address control
bit. If set to 1, the device is transmitting an address. If cleared
to 0, the device is transmitting data. For example, the following
master-based code transmits the slave address followed by the data:
//Setting ENAM, E9BT, E9BR, ETD, NABP
// Slave address is 0xA0
while(!(0x020==(COM0STA0 & 0x020))){} // wait for adr tx to finish.
COM0IEN1
= 0xE6;
COM0TX = 0x55;
//
Clear NAB bit to indicate Data is coming
// Tx data to slave: 0x55
Rev. 0 | Page 61 of 92
ADuC702x Series
Preliminary Technical Data
Table 87. COMxIEN1 MMR Bit Designations
Bit
7
Name
ENAM
6
E9BT
5
E9BR
4
3
ENI
E9BD
2
ETD
1
0
NABP
NAB
Description
Network Address Mode Enable Bit.
Set by user to enable network address mode.
Cleared by user to disable network address mode.
9-Bit Transmit Enable Bit.
Set by user to enable 9-bit transmit. ENAM must be set.
Cleared by user to disable 9-bit transmit.
9-Bit Receive Enable Bit.
Set by user to enable 9-bit receive. ENAM must be set.
Cleared by user to disable 9-bit receive.
Network Interrupt Enable Bit.
Word Length.
Set for 9-bit data. E9BT has to be cleared.
Cleared for 8-bit data.
Transmitter Pin Driver Enable Bit.
Set by user to enable SOUT as an output in slave mode or multimaster mode.
Cleared by user; SOUT is three-state.
Network Address Bit, Interrupt Polarity Bit.
Network Address Bit.
Set by user to transmit the slave’s address.
Cleared by user to transmit data.
Table 88. COMxIID1 MMR Bit Designations
Bit 3:1
Status Bits
000
110
101
011
010
001
000
Bit 0
NINT
1
0
0
0
0
0
0
Priority
2
3
1
2
3
4
Definition
No Interrupt.
Matching Network Address.
Address Transmitted, Buffer Empty.
Receive Line Status Interrupt.
Receive Buffer Full Interrupt.
Transmit Buffer Empty Interrupt.
Modem Status Interrupt.
Note that to receive a network address interrupt, the slave must
ensure that Bit 0 of COMxIEN0 (enable receive buffer full
interrupt) is set to 1.
Clearing Operation
Read COMxRX.
Write data to COMxTX or read COMxIID0.
Read COMxSTA0.
Read COMxRX.
Write data to COMxTX or read COMxIID0.
Read COMxSTA1 register.
COMxADR is an 8-bit, read/write network address register that
holds the address checked for by the network addressable
UART. Upon receiving this address, the device interrupts the
processor and/or sets the appropriate status bit in COMxIID1.
Rev. 0 | Page 62 of 92
ADuC7128/ADuC7129
SERIAL PERIPHERAL INTERFACE
The ADuC7128/ADuC7129 integrate a complete hardware
serial peripheral interface (SPI) on-chip. SPI is an industrystandard synchronous serial interface that allows eight bits
of data to be synchronously transmitted and simultaneously
received, that is, full duplex up to a maximum bit rate of 3.4 Mbs.
The SPI interface is operational only with core clock divider
bits POWCON[2:0] = 0, 1, or 2.
In slave mode, the SPICON register must be configured with
the phase and polarity of the expected input clock. The slave
accepts data from an external master up to 10.4 Mbs at CD = 0.
The formula to determine the maximum speed follows:
f SERIAL CLOCK =
f HCLK
4
The SPI port can be configured for master or slave operation and
typically consists of four pins, namely: MISO, MOSI, SCL, and CS.
In both master and slave modes, data is transmitted on one edge
of the SCL signal and sampled on the other. Therefore, it is
important that the polarity and phase be configured the same
for the master and slave devices.
MISO (Master In, Slave Out) Data I/O Pin
Chip Select (CS) Input Pin
The MISO pin is configured as an input line in master mode
and an output line in slave mode. The MISO line on the master
(data in) should be connected to the MISO line in the slave
device (data out). The data is transferred as byte wide (8-bit)
serial data, MSB first.
In SPI slave mode, a transfer is initiated by the assertion of CS,
which is an active low input signal. The SPI port then transmits
and receives 8-bit data until the transfer is concluded by
desassertion of CS. In slave mode, CS is always an input.
MOSI (Master Out, Slave In) Pin
The MOSI pin is configured as an output line in master mode
and an input line in slave mode. The MOSI line on the master
(data out) should be connected to the MOSI line in the slave
device (data in). The data is transferred as byte wide (8-bit)
serial data, MSB first.
SPI Registers
The following MMR registers are used to control the SPI
interface: SPISTA, SPIRX, SPITX, SPIDIV, and SPICON.
SPISTA Register
Name
SPISTA
Address
0xFFFF0A00
Default Value
0x00
SCL (Serial Clock) I/O Pin
SPISTA is an 8-bit read-only status register.
The master serial clock (SCL) is used to synchronize the data
being transmitted and received through the MOSI SCL period.
Therefore, a byte is transmitted/received after eight SCL periods.
The SCL pin is configured as an output in master mode and as
an input in slave mode.
Table 90. SPISTA MMR Bit Designations
In master mode, polarity and phase of the clock are controlled
by the SPICON register, and the bit rate is defined in the
SPIDIV register as follows:
f SERIAL CLOCK =
f HCLK
2 × (1 + SPIDIV )
Bit
7:6
5
4
3
In slave mode, the SPICON register must be configured with
the phase and polarity of the expected input clock. The slave
accepts data from an external master up to 3.4 Mbs at CD = 0.
2
In both master and slave modes, data is transmitted on one edge
of the SCL signal and sampled on the other. Therefore, it is
important that the polarity and phase be configured the same
for the master and slave devices.
1
The maximum speed of the SPI clock is dependent on the clock
divider bits and is summarized in Table 89.
0
Table 89. SPI Speed vs. Clock Divider Bits in Master Mode
CD Bits
SPIDIV in hex
SPI speed
in MHz
0
0x05
3.482
1
0x0B
1.741
2
0x17
0.870
3
0x2F
0.435
4
0x5F
0.218
5
0xBF
0.109
Rev. 0 | Page 63 of 92
Access
R
Description
Reserved.
SPIRX Data Register Overflow Status Bit.
Set if SPIRX is overflowing.
Cleared by reading SPIRX register.
SPIRX Data Register IRQ.
Set automatically if Bit 3 or Bit 5 is set.
Cleared by reading SPIRX register.
SPIRX Data Register Full Status Bit.
Set automatically if valid data is present in the SPIRX
register.
Cleared by reading SPIRX register.
SPITX Data Register Underflow Status Bit.
Set automatically if SPITX is underflowing.
Cleared by writing in the SPITX register.
SPITX Data Register IRQ.
Set automatically if Bit 0 is clear or Bit 2 is set.
Cleared by writing in the SPITX register or if finished
transmission disabling the SPI.
SPITX Data Register Empty Status Bit.
Set by writing to SPITX to send data. This bit is set
during transmission of data.
Cleared when SPITX is empty.
ADuC7128/ADuC7129
SPIRX Register
Name
SPIRX
Address
0xFFFF0A04
SPIDIV Register
Default Value
0x00
Access
R
SPIRX is an 8-bit read-only receive register.
Address
0xFFFF0A08
Address
0xFFFF0A0C
Default Value
0x1B
Access
R/W
SPIDIV is an 8-bit serial clock divider register.
SPITX Register
Name
SPITX
Name
SPIDIV
SPICON Register
Default Value
0x00
SPITX is an 8-bit write-only transmit register.
Access
W
Name
SPICON
Address
0xFFFF0A10
Default Value
0x0000
Access
R/W
SPICON is a 16-bit control register.
Table 91. SPICON MMR Bit Designations
Bit
15:13
12
11
10
9
8
7
6
5
4
3
2
1
0
Description
Reserved.
Continuous Transfer Enable.
Set by user to enable continuous transfer. In master mode, the transfer continues until no valid data is available in the TX
register. CS is asserted and remains asserted for the duration of each 8-bit serial transfer until TX is empty.
Cleared by user to disable continuous transfer. Each transfer consists of a single 8-bit serial transfer. If valid data exists in the
SPITX register, then a new transfer is initiated after a stall period.
Loopback Enable.
Set by user to connect MISO to MOSI and test software.
Cleared by user to be in normal mode.
Slave Output Enable.
Set by user to enable the slave output.
Cleared by user to disable slave output.
Slave Select Input Enable.
Set by user in master mode to enable the output.
SPIRX Overflow Overwrite Enable.
Set by user, the valid data in the RX register is overwritten by the new serial byte received.
Cleared by user, the new serial byte received is discarded.
SPITX Underflow Mode.
Set by user to transmit 0.
Cleared by user to transmit the previous data.
Transfer and Interrupt Mode (Master Mode).
Set by user to initiate transfer with a write to the SPITX register. Interrupt occurs when TX is empty.
Cleared by user to initiate transfer with a read of the SPIRX register. Interrupt occurs when RX is full.
LSB First Transfer Enable Bit.
Set by user, the LSB is transmitted first.
Cleared by user, the MSB is transmitted first.
Reserved. Should be set to 0.
Serial Clock Polarity Mode Bit.
Set by user, the serial clock idles high.
Cleared by user, the serial clock idles low.
Serial Clock Phase Mode Bit.
Set by user, the serial clock pulses at the beginning of each serial bit transfer.
Cleared by user, the serial clock pulses at the end of each serial bit transfer.
Master Mode Enable Bit.
Set by user to enable master mode.
Cleared by user to enable slave mode.
SPI Enable Bit.
Set by user to enable the SPI.
Cleared to disable the SPI.
Rev. 0 | Page 64 of 92
ADuC7128/ADuC7129
I2C-COMPATIBLE INTERFACES
Slave Addresses
The ADuC7128/ADuC7129 support two fully licensed I2C
interfaces. The I2C interfaces are both implemented as full
hardware master and slave interfaces. Because the two I2C
interfaces are identical, only I2C0 is described in detail. Note
that the two masters and slaves have individual interrupts.
Register I2C0ID0, Register I2C0ID1, Register I2C0ID2, and
Register I2C0ID3 contain the device IDs. The device compares
the four I2C0IDx registers to the address byte. The seven most
significant bits of either ID register must be identical to that of
the seven most significant bits of the first address byte received
to be correctly addressed. The LSB of the ID registers, transfer
direction bit, is ignored in the process of address recognition.
Note that when configured as an I2C master device, the
ADuC7128/ADuC7129 cannot generate a repeated start
condition.
I2C REGISTERS
The two pins used for data transfer, SDA and SCL, are configured
in a wire-AND’ed format that allows arbitration in a multimaster
system. These pins require external pull-up resistors. Typical
pull-up values are 10 kΩ.
The I2C bus peripheral addresses in the I2C bus system are
programmed by the user. This ID can be modified any time a
transfer is not in progress. The user can configure the interface
to respond to four slave addresses.
The I2C peripheral interface consists of 18 MMRs that are
discussed in this section.
I2CxMSTA Register
Name
I2C0MSTA
I2C1MSTA
Address
0xFFFF0800
0xFFFF0900
Default Value
0x00
0x00
I2CxMSTA is a status register for the master channel.
The transfer sequence of an I2C system consists of a master
device initiating a transfer by generating a start condition while
the bus is idle. The master transmits the address of the slave
device and the direction of the data transfer in the initial
address transfer. If the master does not lose arbitration and the
slave acknowledges, then the data transfer is initiated. This
continues until the master issues a stop condition and the bus
becomes idle.
Table 92. I2C0MSTA MMR Bit Designations
The I2C peripheral master and slave functionality are
independent and can be simultaneously active. A slave is
activated when a transfer has been initiated on the bus.
5
If it is not addressed, it remains inactive until another transfer is
initiated. This also allows a master device, which has lost
arbitration, to respond as a slave in the same cycle.
4
Serial Clock Generation
3
The I2C master in the system generates the serial clock for a
transfer. The master channel can be configured to operate in
fast mode (400 kHz) or standard mode (100 kHz).
Bit
7
6
2
The bit rate is defined in the I2C0DIV MMR as follows:
f S ERIAL CLOCK =
fUCLK
(2 + DIVH ) + (2 + DIVL)
where:
fUCLK is the clock before the clock divider.
DIVH is the high period of the clock.
DIVL is the low period of the clock.
Access
R
R
1
0
Thus, for 100 kHz operation
DIVH = DIVL = 0xCF
and for 400 kHz
DIVH = 0x28 DIVL = 0x3C.
The I2CxDIV register corresponds to DIVH:DIVL.
Rev. 0 | Page 65 of 92
Description
Master Transmit FIFO Flush.
Set by user to flush the master Tx FIFO.
Cleared automatically once the master Tx FIFO is flushed.
This bit also flushes the slave receive FIFO.
Master Busy.
Set automatically if the master is busy.
Cleared automatically.
Arbitration Loss.
Set in multimaster mode if another master has the bus.
Cleared when the bus becomes available.
No Acknowledge.
Set automatically if there is no acknowledge of the
address by the slave device.
Cleared automatically by reading the I2C0MSTA register.
Master Receive IRQ.
Set after receiving data.
Cleared automatically by reading the I2C0MRX register.
Master Transmit IRQ.
Set at the end of a transmission.
Cleared automatically by writing to the I2C0MTX register.
Master Transmit FIFO Underflow.
Set automatically if the master transmit FIFO is
underflowing.
Cleared automatically by writing to the I2C0MTX register.
Master TX FIFO Not Full.
Set automatically if the slave transmit FIFO is not full.
Cleared automatically by writing twice to the I2C0STX
register.
ADuC7128/ADuC7129
I2CxSSTA Register
Name
I2C0SSTA
I2C1SSTA
Address
0xFFFF0804
0xFFFF0904
Default Value
0x01
0x01
Access
R
R
I2CxSSTA is a status register for the slave channel.
Table 93. I2CxSSTA MMR Bit Designations
Bit
31:15
14
Value
13
12:11
00
01
10
11
10
9:8
00
01
10
11
7
6
5
4
3
2
1
0
Description
Reserved. These bits should be written as 0.
START Decode Bit.
Set by hardware if the device receives a valid start and matching address.
Cleared by an I2C stop condition or an I2C general call reset.
Repeated START Decode Bit.
Set by hardware if the device receives a valid repeated start and matching address.
Cleared by an I2C stop condition, a read of the I2CxSSTA register, or an I2C general call reset.
ID Decode Bits.
Received Address Matched ID Register 0.
Received Address Matched ID Register 1.
Received Address Matched ID Register 2.
Received Address Matched ID Register 3.
Stop After Start And Matching Address Interrupt.
Set by hardware if the slave device receives an I2C STOP condition after a previous I2C START condition
and matching address.
Cleared by a read of the I2CxSSTA register.
General Call ID.
No General Call.
General Call Reset and Program Address.
General Call Program Address.
General Call Matching Alternative ID.
General Call Interrupt.
Set if the slave device receives a general call of any type.
Cleared by setting Bit 8 of the I2CxCFG register. If it is a general call reset, all registers are at their default
values. If it is a hardware general call, the Rx FIFO holds the second byte of the general call. This is similar
to the I2C0ALT register (unless it is a general call to reprogram the device address). For more details, see
the I2C Bus Specification, Version 2.1, Jan. 2000.
Slave Busy.
Set automatically if the slave is busy.
Cleared automatically.
No Acknowledge.
Set if master asks for data and no data is available.
Cleared automatically by reading the I2C0SSTA register.
Slave Receive FIFO Overflow.
Set automatically if the slave receive FIFO is overflowing.
Cleared automatically by reading I2C0SRX register.
Slave Receive IRQ.
Set after receiving data.
Cleared automatically by reading the I2C0SRX register or flushing the FIFO.
Slave Transmit IRQ.
Set at the end of a transmission.
Cleared automatically by writing to the I2C0STX register.
Slave Transmit FIFO Underflow.
Set automatically if the slave transmit FIFO is underflowing.
Cleared automatically by writing to the I2C0STX register.
Slave Transmit FIFO Empty.
Set automatically if the slave transmit FIFO is empty.
Cleared automatically by writing twice to the I2C0STX register.
Rev. 0 | Page 66 of 92
I2CxADR Register
I2CxSRX Register
Name
I2C0SRX
I2C1SRX
Address
0xFFFF0808
0xFFFF0908
Default Value
0x00
0x00
Access
R
R
I2CxSRX is a receive register for the slave channel.
I2CxSTX Register
Name
I2C0STX
I2C1STX
Address
0xFFFF080C
0xFFFF090C
Default Value
0x00
0x00
Access
W
W
I2CxMRX Register
Address
0xFFFF0810
0xFFFF0910
Default Value
0x00
0x00
Access
R
R
I2CxMTX Register
Address
0xFFFF0814
0xFFFF0914
Default Value
0x00
0x00
Access
W
W
I2CxCNT Register
Address
0xFFFF0818
0xFFFF0918
Default Value
0x00
0x00
Access
R/W
R/W
I2CxADR is a master address byte register. The I2CxADR value
is the device address that the master wants to communicate
with. It is automatically transmitted at the start of a master
transfer sequence if there is no valid data in the I2CxMTX
register when the master enable bit is set.
Name
I2C0BYT
I2C1BYT
Address
0xFFFF0824
0xFFFF0924
Default Value
0x00
0x00
Access
R/W
R/W
I2CxBYT is a broadcast byte register.
Name
I2C0ALT
I2C1ALT
Address
0xFFFF0828
0xFFFF0928
Default Value
0x00
0x00
Access
R/W
R/W
I2CxALT is a hardware general call ID register used in slave mode.
I2CxCFG Register
I2CxMTX is a transmit register for the master channel.
Name
I2C0CNT
I2C1CNT
Default Value
0x00
0x00
I2CxALT Register
I2CxMRX is a receive register for the master channel.
Name
I2C0MTX
I2C1MTX
Address
0xFFFF081C
0xFFFF091C
I2CxBYT Register
I2CxSTX is a transmit register for the slave channel.
Name
I2C0MRX
I2C1MRX
Name
I2C0ADR
I2C1ADR
Access
R/W
R/W
Name
I2C0CFG
I2C1CFG
Address
0xFFFF082C
0xFFFF092C
Default Value
0x00
0x00
Access
R/W
R/W
I2CxCFG is a configuration register.
I2CxCNT is a master receive data count register. If a master read
transfer sequence is initiated, the I2CxCNT register denotes the
number of bytes (−1) to be read from the slave device. By default
this counter is 0, which corresponds to the expected one byte.
Table 94. I2C0CFG MMR Bit Designations
Bit
31:15
14
13
12
11
10
9
8
Description
Reserved. These bits should be written by the user as 0.
Enable Stop Interrupt.
Set by user to generate an interrupt upon receiving a stop condition and after receiving a valid start condition and matching
address.
Cleared by user to disable the generation of an interrupt upon receiving a stop condition.
Reserved. This bit should be written by the user as 0.
Reserved. This bit should be written by the user as 0.
Enable Stretch SCL. Holds SCL low.
Set by user to stretch the SCL line.
Cleared by user to disable stretching of the SCL line.
Reserved. This bit should be written by the user as 0.
Slave Tx FIFO Request Interrupt Enable.
Cleared by user to generate an interrupt request just after the negative edge of the clock for the R/W bit. This allows the user to
input data into the slave Tx FIFO if it is empty. At 400 kSPS, and with the core clock running at 41.78 MHz, the user has 45 clock
cycles to take appropriate action, taking interrupt latency into account.
Set by user to disable the slave Tx FIFO request interrupt.
General Call Status Bit Clear.
Set by user to clear the general call status bits.
Cleared automatically by hardware after the general call status bits have been cleared.
Rev. 0 | Page 67 of 92
ADuC7128/ADuC7129
Bit
7
6
5
4
3
2
1
0
Description
Master Serial Clock Enable Bit.
Set by user to enable generation of the serial clock in master mode.
Cleared by user to disable serial clock in master mode.
Loop-Back Enable Bit.
Set by user to internally connect the transition to the reception to test user software.
Cleared by user to operate in normal mode.
Start Back-Off Disable Bit.
Set by user in multimaster mode. If losing arbitration, the master immediately tries to retransmit.
Cleared by user to enable start back-off. After losing arbitration, the master waits before trying to retransmit.
Hardware General Call Enable. When this bit and Bit 3 are set, and have received a general call (Address 0x00) and a data byte, the
device checks the contents of the I2C0ALT against the receive register. If the contents match, the device has received a hardware
general call. This is used if a device needs urgent attention from a master device without knowing which master it needs to turn to.
This is a “to whom it may concern” call. The ADuC7128/ADuC7129 watch for these addresses. The device that requires attention
embeds its own address into the message. All masters listen and the one that can handle the device contacts its slave and acts
appropriately. The LSB of the I2C0ALT register should always be written to a 1, as per the I2C January 2000 specification.
General Call Enable Bit.
Set this bit to enable the slave device to acknowledge an I2C general call, Address 0x00 (write). The device then recognizes a data
bit. If it receives a 0x06 (reset and write programmable part of slave address by hardware) as the data byte, the I2C interface resets as per
the I2C January 2000 specification. This command can be used to reset an entire I2C system. The general call interrupt status bit
sets on any general call. The user must take corrective action by setting up the I2C interface after a reset. If it receives a 0x04
(write programmable part of slave address by hardware) as the data byte, the general call interrupt status bit sets on any general
call. The user must take corrective action by reprogramming the device address.
Reserved.
Master Enable Bit.
Set by user to enable the master I2C channel.
Cleared by user to disable the master I2C channel.
Slave Enable Bit.
Set by user to enable the slave I2C channel. A slave transfer sequence is monitored for the device address in I2C0ID0, I2C0ID1,
I2C0ID2, and I2C0ID3. If the device address is recognized, the part participates in the slave transfer sequence.
Cleared by user to disable the slave I2C channel.
I2CxDIV Register
Name
I2C0DIV
I2C1DIV
Address
0xFFFF0830
0xFFFF0930
I2CxSSC Register
Default Value
0x1F1F
0x1F1F
Access
R/W
R/W
I2CxDIV are the clock divider registers.
Address
0xFFFF0838
0xFFFF083C
0xFFFF0840
0xFFFF0844
0xFFFF0938
0xFFFF093C
0xFFFF0940
0xFFFF0944
Default Value
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
Address
0xFFFF0848
0xFFFF0948
Default Value
0x01
0x01
Access
R/W
R/W
I2CxSSC is an 8-bit start/stop generation counter. It holds off
SDA low for start and stop conditions.
I2CxIDx Register
Name
I2C0ID0
I2C0ID1
I2C0ID2
I2C0ID3
I2C1ID0
I2C1ID1
I2C1ID2
I2C1ID3
Name
I2C0SSC
I2C1SSC
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
I2CxID0, I2CxID1, I2CxID2, and I2CxID3 are slave address
device ID registers of I2Cx.
Rev. 0 | Page 68 of 92
ADuC7128/ADuC7129
I2CxFIF Register
Name
I2C0FIF
I2C1FIF
Address
0xFFFF084C
0xFFFF094C
Default Value
0x0000
0x0000
Access
R
R
I2CxFIF is a FIFO status register.
Table 95. I2C0FIF MMR Bit Designations
Bit
15:10
9
Value
8
7:6
00
01
10
11
5:4
00
01
10
11
3:2
00
01
10
11
1:0
00
01
10
11
Description
Reserved.
Master Transmit FIFO Flush.
Set by user to flush the master Tx FIFO.
Cleared automatically once the master Tx FIFO is flushed. This bit also flushes the slave receive FIFO.
Slave Transmit FIFO Flush.
Set by user to flush the slave Tx FIFO.
Cleared automatically once the slave Tx FIFO is flushed.
Master Rx FIFO Status Bits.
FIFO Empty.
Byte Written to FIFO.
1 Byte in FIFO.
FIFO Full.
Master Tx FIFO Status Bits.
FIFO Empty.
Byte Written to FIFO.
1 Byte in FIFO.
FIFO Full.
Slave Rx FIFO Status Bits.
FIFO Empty.
Byte Written to FIFO.
1 Byte in FIFO.
FIFO Full.
Slave Tx FIFO Status Bits.
FIFO Empty.
Byte Written to FIFO.
1 Byte in FIFO.
FIFO full.
PROGRAMMABLE LOGIC ARRAY (PLA)
The ADuC7128/ADuC7129 integrate a fully programmable
logic array (PLA) that consists of two independent but
interconnected PLA blocks. Each block consists of eight PLA
elements, giving a total of 16 PLA elements.
A PLA element contains a two input look-up table that can be
configured to generate any logic output function based on two
inputs and a flip-flop as represented in Figure 54.
2
4
LOOK-UP
TABLE
3
The PLA is configured via a set of user MMRs and the output(s)
of the PLA can be routed to the internal interrupt system, to the
CONVST signal of the ADC, to an MMR, or to any of the
16 PLA output pins.
The interconnection between the two blocks is supported by
connecting the output of Element 7 of Block 1 fed back to the
Input 0 of Mux 0 of Element 0 of Block 0, and the output of
Element 7 of Block 0 is fed back to the Input 0 of Mux 0 of
Element 0 of Block 1.
0
A
In total, 30 GPIO pins are available on the ADuC7128/ADuC7129
for the PLA. These include 16 input pins and 14 output pins.
They need to be configured in the GPxCON register as PLA
pins before using the PLA. Note that the comparator output is
also included as one of the 16 input pins.
B
06020-049
1
Figure 54. PLA Element
Rev. 0 | Page 69 of 92
ADuC7128/ADuC7129
Table 96. Element Input/Output
Table 97. PLA MMRs
PLA Block 0
Element Input Output
0
P1.0
P1.7
1
P1.1
P0.4
2
P1.2
P0.5
3
P1.3
P0.6
4
P1.4
P0.7
5
P1.5
P2.0
6
P1.6
P2.1
7
P0.0
P2.2
Name
PLAELMx
PLA Block 1
Element Input Output
8
P3.0
P4.0
9
P3.1
P4.1
10
P3.2
P4.2
11
P3.3
P4.3
12
P3.4
P4.4
13
P3.5
P4.5
14
P3.6
P4.6
15
P3.7
P4.7
PLACLK
PLAIRQ
PLAADC
PLADIN
PLAOUT
PLA MMRs Interface
The PLA peripheral interface consists on 21 MMRs, as shown
in Table 97.
Description
Element 0 to Element 15 Control Registers.
Configure the input and output mux of each
element, select the function in the look-up table,
and bypass/use the flip-flop.
Clock Selection for the Flip-Flops of Block 0 and
Clock Selection for the Flip-Flops of Block 1.
Enable IRQ0 and/or IRQ1. Select the source of the IRQ.
PLA Source from ADC Start Conversion Signal.
Data Input MMR for PLA.
Data Output MMR for PLA. This register is always
updated.
A PLA tool is provided in the development system to easily
configure the PLA.
Table 98. PLAELMx MMR Bit Designations
Bit
31:11
10:9
8:7
Value
PLAELM0
PLAELM1 to
PLAELM7
PLAELM8
PLAELM9 to
PLAELM15
00
01
10
11
00
01
10
11
Element 15
Element 2
Element 4
Element 6
Element 1
Element 3
Element 5
Element 7
Element 0
Element 2
Element 4
Element 6
Element 1
Element 3
Element 5
Element 7
Element 7
Element 10
Element 12
Element 14
Element 9
Element 11
Element 13
Element 15
Element 8
Element 10
Element 12
Element 14
Element 9
Element 11
Element 13
Element 15
6
5
4:1
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
0
Description
Reserved.
Mux (0) Control. Select feedback source.
Mux (1) Control. Select feedback source.
Mux (2) Control.
Set by user to select the output of Mux (0).
Cleared by user to select the bit value from PLADIN.
Mux (3) Control.
Set by user to select the input pin of the particular element.
Cleared by user to select the output of Mux (1).
Look-Up Table Control.
0
NOR
B AND NOT A
NOT A
A AND NOT B
NOT B
EXOR
NAND
AND
EXNOR
B
NOT A OR B
A
A OR NOT B
OR
1
Mux (4) Control.
Set by user to bypass the flip-flop.
Cleared by user to select the flip-flop.
Cleared by default.
Rev. 0 | Page 70 of 92
Table 99. PLACLK MMR Bit Designations
Table 101. PLAADC MMR Bit Designations
Bit
7
6:4
Bit
31:5
4
Value
000
001
010
011
100
101
110
Other
3
2:0
000
001
010
011
100
101
110
Other
Description
Reserved.
Block 1 Clock Source Selection.
GPIO Clock on P0.5.
GPIO Clock on P0.0.
GPIO Clock on P0.7.
HCLK.
OCLK.
Timer1 Overflow.
Timer4 Overflow.
Reserved.
Reserved.
Block 0 Clock Source Selection.
GPIO Clock on P0.5.
GPIO Clock on P0.0.
GPIO Clock on P0.7.
HCLK.
OCLK.
Timer1 Overflow.
Timer4 Overflow.
Reserved.
3:0
0000
0001
…
1111
Value
11:8
0000
0001
…
1111
7:5
4
3:0
0000
0001
…
1111
Description
Reserved.
ADC Start Conversion Enable Bit.
Set by user to enable ADC start conversion
from PLA.
Cleared by user to disable ADC start
conversion from PLA.
ADC Start Conversion Source.
PLA Element 0.
PLA Element 1.
PLA Element 15.
Table 102. PLADIN MMR Bit Designations
Bit
31:16
15:0
Description
Reserved.
Input Bit from Element 15 to Element 0.
Table 103. PLAOUT MMR Bit Designations
Bit
31:16
15:0
Table 100. PLAIRQ MMR Bit Designations
Bit
15:13
12
Value
Description
Reserved.
PLA IRQ1 Enable Bit
Set by user to enable IRQ1 output from PLA
Cleared by user to disable IRQ1 output
from PLA
PLA IRQ1 Source.
PLA Element 0.
PLA Element 1.
PLA Element 15.
Reserved.
PLA IRQ0 Enable Bit.
Set by user to enable IRQ0 output from PLA.
Cleared by user to disable IRQ0 output
from PLA.
PLA IRQ0 Source.
PLA Element 0.
PLA Element 1.
PLA Element 15.
Rev. 0 | Page 71 of 92
Description
Reserved.
Output Bit from Element 15 to Element 0.
ADuC7128/ADuC7129
PROCESSOR REFERENCE PERIPHERALS
INTERRUPT SYSTEM
IRQ
There are 30 interrupt sources on the ADuC7128/ADuC7129
controlled by the interrupt controller. Most interrupts are generated
from the on-chip peripherals, such as ADC and UART. Two
additional interrupt sources are generated from external interrupt
request pins, XIRQ0 and XIRQ1. The ARM7TDMI CPU core
only recognizes interrupts as one of two types: a normal interrupt
request (IRQ) or a fast interrupt request (FIQ). All the interrupts
can be masked separately.
The interrupt request (IRQ) is the exception signal to enter the
IRQ mode of the processor. It is used to service generalpurpose interrupt handling of internal and external events.
The control and configuration of the interrupt system are managed
through nine interrupt-related registers, four dedicated to IRQ,
four dedicated to FIQ, and an additional MMR that is used to
select the programmed interrupt source. The bits in each IRQ
and FIQ register represent the same interrupt source as described
in Table 104.
The four 32-bit registers dedicated to IRQ are listed in Table 105.
Table 105. IRQ Interface MMRs
Register
IRQSIG
IRQEN
Table 104. IRQ/FIQ MMRs Bit Designations
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
Description
FIQ Source.
SWI. Not used in IRQEN/CLR and FIQEN/CLR.
Timer0.
Timer1.
Wake-Up Timer—Timer2.
Watchdog Timer—Timer3.
Timer4.
Flash Controller 0.
Flash Controller 1.
ADC.
Quadrature Encoder.
I2C0 Slave.
I2C1 Slave.
I2C0 Master.
I2C1 Master.
SPI Slave.
SPI Master.
UART0.
UART1.
External IRQ0.
Comparator.
PSM.
External IRQ1.
PLA IRQ0.
PLA IRQ1.
External IRQ2.
External IRQ3.
PWM Trip.
PLL Lock.
Reserved.
Reserved.
IRQCLR
IRQSTA
Description
Reflects the status of the different IRQ sources.
If a peripheral generates an IRQ signal, the
corresponding bit in the IRQSIG is set; otherwise,
it is cleared. The IRQSIG bits are cleared when the
interrupt in the particular peripheral is cleared. All
IRQ sources can be masked in the IRQEN MMR.
IRQSIG is read only.
Provides the value of the current enable mask. When
set to 1, the source request is enabled to create an
IRQ exception. When set to 0, the source request is
disabled or masked but does not create an IRQ
exception. To clear a bit in IRQEN, use the IRQCLR MMR.
Write-only register allows clearing the IRQEN register
to mask an interrupt source. Each bit set to 1 clears
the corresponding bit in the IRQEN register without
affecting the remaining bits. The pair of registers,
IRQEN and IRQCLR, allows independent manipulation
of the enable mask without requiring an automatic
read-modify-write.
Read-only register provides the current enabled IRQ
source status. When set to 1, that source should
generate an active IRQ request to the ARM7TDMI
core. There is no priority encoder or interrupt vector
generation. This function is implemented in software
in a common interrupt handler routine. All 32 bits are
logically OR’ed to create the IRQ signal to the
ARM7TDMI core.
FIQ
The fast interrupt request (FIQ) is the exception signal to enter
the FIQ mode of the processor. It is provided to service data
transfer or communication channel tasks with low latency. The
FIQ interface is identical to the IRQ interface providing the
second level interrupt (highest priority). Four 32-bit registers
are dedicated to FIQ: FIQSIG, FIQEN, FIQCLR, and FIQSTA.
Bit 31 to Bit 1 of FIQSTA are logically OR’ed to create the FIQ
signal to the core and Bit 0 of both the FIQ and IRQ registers
(FIQ source).
The logic for FIQEN and FIQCLR does not allow an interrupt
source to be enabled in both IRQ and FIQ masks. A bit set
to 1 in FIQEN, as a side effect, clears the same bit in IRQEN.
A bit set to 1 in IRQEN, as a side effect, clears the same bit
in FIQEN. An interrupt source can be disabled in both IRQEN and
FIQEN masks.
Rev. 0 | Page 72 of 92
ADuC7128/ADuC7129
Programmed Interrupts
In normal mode, an IRQ is generated each time the value of the
counter reaches zero, if counting down; or full scale, if counting
up. An IRQ can be cleared by writing any value to clear the register
of the particular timer (TxICLR).
As the programmed interrupts are nonmaskable, they are
controlled by the SWICFG register that writes into both the
IRQSTA and IRQSIG registers and/or FIQSTA and FIQSIG
registers at the same time. The 32-bit register dedicated to
software interrupt is SWICFG described in Table 106. This
MMR allows the control of programmed source interrupt.
Table 107. Event Selection Numbers
Table 106. SWICFG MMR Bit Designations
Bit
31:3
2
1
0
Description
Reserved.
Programmed Interrupt (FIQ). Setting/clearing this bit
corresponds to setting/clearing Bit 1 of FIQSTA and
FIQSIG.
Programmed Interrupt (IRQ). Setting/clearing this bit
corresponds to setting/clearing Bit 1 of IRQSTA and
IRQSIG.
Reserved.
Note that any interrupt signal must be active for at least the
equivalent of the interrupt latency time, to be detected by the
interrupt controller and to be detected by the user in the
IRQSTA/FIQSTA register.
TIMERS
The ADuC7128/ADuC7129 have five general purpose
timers/counters.
•
•
•
•
•
ES
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01011
01100
01101
01110
01111
10000
10001
Interrupt Number
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
Name
RTOS Timer (Timer0)
GP Timer0 (Timer1)
Wake-Up Timer (Timer2)
Watchdog Timer (Timer3)
GP Timer1 (Timer4)
Flash Control 0
Flash Control 1
ADC Channel
Quadrature Encoder
I2C Slave0
I2C Slave1
I2C Master0
I2C Master1
SPI Slave
SPI Master
UART0
UART1
External IRQ0
TIMER0—LIFETIME TIMER
Timer0
Timer1
Timer2 or wake-up timer
Timer3 or watchdog timer
Timer4
Timer0 is a general-purpose, 48-bit count up, or a 16-bit count
up/down timer with a programmable prescaler. Timer0 is
clocked from the core clock, with a prescaler of 1, 16, 256, or
32,768. This gives a minimum resolution of 22 ns when the core
is operating at 41.78 MHz and with a prescaler of 1.
The five timers in their normal mode of operation can be either
free-running or periodic.
In 48-bit mode, Timer0 counts up from zero. The current
counter value can be read from T0VAL0 and T0VAL1.
In free-running mode, the counter decrements or increments
from the maximum or minimum value until zero scale or full
scale and starts again at the maximum or minimum value.
In 16-bit mode, Timer0 can count up or count down. A 16-bit
value can be written to T0LD, which is loaded into the counter.
The current counter value can be read from T0VAL0. Timer0 has
a capture register (T0CAP) that can be triggered by a selected IRQ
source initial assertion. Once triggered, the current timer value is
copied to T0CAP, and the timer keeps running. This feature can be
used to determine the assertion of an event with more accuracy
than by servicing an interrupt alone.
In periodic mode, the counter decrements/increments from the
value in the load register (TxLD MMR) until zero scale or full
scale and starts again at the value stored in the load register.
The value of a counter can be read at any time by accessing its
value register (TxVAL). Timers are started by writing in the
control register of the corresponding timer (TxCON).
Timer0 reloads the value from T0LD either when TIMER0
overflows or immediately when T0ICLR is written.
Rev. 0 | Page 73 of 92
ADuC7128/ADuC7129
The Timer0 interface consists of six MMRs, shown in Table 108.
Timer0 Control Register
Table 108. Timer0 Interface MMRs
Name
T0CON
Name
T0LD
T0CAP
T0VAL0/
T0VAL1
T0ICLR
T0CON
Description
A 16-bit register that holds the 16-bit value loaded
into the counter. Available only in 16-bit mode.
A 16-bit register that holds the 16-bit value captured
by an enabled IRQ event. Available only in 16-bit mode.
TOVAL0 is a 16 bit register that holds the 16 least
significant bits (LSBs).
T0VAL1 is a 32-bit register that holds the 32 most
significant bits (MSBs).
T0VAL0 and T0VAL1 are read only. In 16-bit mode, 16bit T0VAL0 is used. In 48-bit mode, both 16-bit T0VAL0
and 32-bit T0VAL1 are used.
An 8-bit register. Writing any value to this register
clears the interrupt. Available only in 16-bit mode.
The configuration MMR (see Table 109).
16-BIT LOAD
CORE CLOCK
FREQUENCY
PRESCALER 1,
16, 256, OR 32768
48-BIT
UP COUNTER
16-BIT
UP/DOWN COUNTER
Address
0xFFFF030C
Table 109. T0CON MMR Bit Designations
Bit
31:18
17
Value
16:12
11
10:9
8
TIMER0IRQ
7
06020-050
6
CAPTURE
Figure 55. Timer0 Block Diagram
5
4
Timer0 Value Register
Name
T0VAL0
T0VAL1
Address
0xFFFF0304
0xFFFF0308
Default Value
0x00
0x00
Access
R
R
T0VAL0 and T0VAL1 are 16-bit and 32-bit registers that hold
the 16 least significant bits and 32 most significant bits,
respectively. T0VAL0 and T0VAL1 are read-only. In 16-bit
mode, 16-bit T0VAL0 is used. In 48-bit mode, both 16-bit
T0VAL0 and 32-bit T0VAL1 are used.
Timer0 Capture Register
Name
T0CAP
Address
0xFFFF0314
Default Value
0x00
Access
R
This is a 16-bit register that holds the 16-bit value captured by
an enabled IRQ event; available only in 16-bit mode.
Access
R/W
The 17-bit MMR configures the mode of operation of Timer0.
TIMER0 VALUE
IRQ[31:0]
Default Value
0x00
0
1
3:0
0000
0100
1000
1111
Description
Reserved.
Event Select Bit.
Set by user to enable time capture of an
event.
Cleared by user to disable time capture of
an event.
Event Select Range, 0 to 31. The events are as
described in the Timers section.
Reserved.
Reserved.
Count Up. Available only in 16-bit mode.
Set by user for timer 0 to count up.
Cleared by user for timer 0 to count down
(default).
Timer0 Enable Bit.
Set by user to enable Timer0.
Cleared by user to disable Timer0 (default).
Timer0 Mode.
Set by user to operate in periodic mode.
Cleared by user to operate in free-running
mode (default).
Reserved.
Timer0 Mode of Operation.
16-bit operation (default).
48-bit operation.
Prescaler.
Source clock/1 (default).
Source clock/16.
Source clock/256.
Source clock/32,768.
Timer0 Load Register
Name
T0LD
Address
0xFFFF0300
Default Value
0x00
Access
R/W
T0LD is a 16-bit register that holds the 16-bit value that is
loaded into the counter; available only in 16-bit mode.
Timer0 Clear Register
Name
T0ICLR
Address
0xFFFF0310
Default Value
0x00
Access
W
This 8-bit, write-only MMR is written (with any value) by user
code to refresh (reload) Timer0.
Rev. 0 | Page 74 of 92
ADuC7128/ADuC7129
Timer1 reloads the value from T1LD either when Timer1
overflows or immediately after T1ICLR is written.
TIMER1—GENERAL-PURPOSE TIMER
32-BIT LOAD
32.768kHz
OSCILLATOR
Timer1 Load Register
CORE CLOCK
FREQUENCY
PRESCALER
1, 16, 256,
OR 32768
GPIO
32-BIT
UP/DOWN COUNTER
Name
Address
Default Value
Access
T1LD
0xFFFF0320
0x00000
R/W
T1LD is a 32-bit register that holds the 32-bit value that is loaded
into the counter.
TIMER1IRQ
GPIO
IRQ[31:0]
06020-051
TIMER1 VALUE
CAPTURE
Figure 56. Timer1 Block Diagram
Timer1 Clear Register
Name
T1ICLR
Address
0xFFFF032C
Default Value
0x00
Access
W
Timer1 is a 32-bit general-purpose count down or count up timer
with a programmable prescaler. The prescaler source can be
from the 32 kHz oscillator, the core clock, or one of two external
GPIOs. This source can be scaled by a factor of 1, 16, 256, or
32,768. This gives a minimum resolution of 42 ns when operating
at CD zero, the core is operating at 41.78 MHz, and with a
prescaler of 1 (ignoring external GPIO).
This 8-bit, write-only MMR is written (with any value) by user
code to refresh (reload) Timer1.
The counter can be formatted as a standard 32-bit value or as
hours:minutes:seconds:hundredths.
Timer1 Capture Register
Timer1 has a capture register (T1CAP) that can be triggered by
a selected IRQ source initial assertion. Once triggered, the
current timer value is copied to T1CAP, and the timer keeps
running. This feature can be used to determine the assertion of
an event with increased accuracy.
This is a 32-bit register that holds the 32-bit value captured by
an enabled IRQ event.
The Timer1 interface consists of five MMRs, as shown in Table 110.
Timer1 Value Register
Name
T1VAL
T1VAL
T1CAP
T1ICLR
T1CON
Default Value
0x0000
Access
R
T1VAL is a 32-bit register that holds the current value of Timer1.
Name
T1CAP
Address
0xFFFF0330
Default Value
0x00
Access
R
Timer1 Control Register
Name
Address
Default Value
Access
T1CON
0xFFFF0328
0x0000
R/W
This 32-bit MMR configures the mode of operation of Timer1.
Table 110. Timer1 Interface MMRs
Name
T1LD
Address
0xFFFF0324
Description
A 32-bit register. Holds 32-bit unsigned integers.
This register is read only.
A 32-bit register. Holds 32-bit unsigned integers.
A 32-bit register. Holds 32-bit unsigned integers.
This register is read only.
An 8-bit register. Writing any value to this register
clears the Timer1 interrupt.
The configuration MMR (see Table 111).
Note that if the part is in a low power mode, and Timer1 is
clocked from the GPIO or low power oscillator source, then
Timer1 continues to operate.
Rev. 0 | Page 75 of 92
ADuC7128/ADuC7129
Table 111. T1CON MMR Bit Designations
Bit
31:18
17
Value
16:12
11:9
000
001
010
011
8
7
6
5:4
00
01
10
11
3:0
0000
0100
1000
1111
Description
Reserved. Should be set to 0 by the user.
Event Select Bit.
Set by user to enable time capture of an event.
Cleared by user to disable time capture of an event.
Event Select Range, 0 to 31. The events are as described in the introduction to the timers.
Clock Select.
Core Clock (Default).
32.768 kHz Oscillator.
P1.0.
P0.6.
Count Up.
Set by user for Timer1 to count up.
Cleared by user for Timer1 to count down (default).
Timer1 Enable Bit.
Set by user to enable Timer1.
Cleared by user to disable Timer1 (default).
Timer1 Mode.
Set by user to operate in periodic mode.
Cleared by user to operate in free-running mode (default).
Format.
Binary (Default).
Reserved.
Hours:Minutes:Seconds:Hundredths: 23 Hours to 0 Hours.
Hours:Minutes:Seconds:Hundredths: 255 Hours to 0 Hours.
Prescaler.
Source Clock/1 (Default).
Source Clock/16.
Source Clock/256.
Source Clock/32768.
Rev. 0 | Page 76 of 92
ADuC7128/ADuC7129
Timer2 Load Register
TIMER2—WAKE-UP TIMER
Name
T2LD
32-BIT
LOAD
EXTERNAL 32kHz
OSCILLATOR
INTERNAL 32kHz
OSCILLATOR
PRESCALER
1, 16, 256,
OR 32768
32-BIT
UP/DOWN
COUNTER
Address
0xFFFF0340
Default Value
0x00000
Access
R/W
T2LD is a 32-bit register that holds the 32 bit value that is loaded
into the counter.
TIMER2IRQ
TIMER2
VALUE
06020-052
CORE CLOCK
Figure 57. Timer2 Block Diagram
Timer2 Clear Register
Name
T2ICLR
Address
0xFFFF034C
Default Value
0x00
Access
W
Timer2 is a 32-bit wake-up timer, count down or count up, with
a programmable prescaler. The prescaler is clocked directly from
one of four clock sources, namely, the core clock (default selection),
the internal 32.768 kHz oscillator, the external 32.768 kHz watch
crystal, or the core clock. The selected clock source can be
scaled by a factor of 1, 16, 256, or 32768. The wake-up timer
continues to run when the core clock is disabled. This gives
a minimum resolution of 22 ns when the core is operating at
41.78 MHz and with a prescaler of 1. Capture of the current
timer value is enabled if the Timer2 interrupt is enabled via
IRQEN[4].
This 8-bit write-only MMR is written (with any value) by user
code to refresh (reload) Timer2.
The counter can be formatted as plain 32-bit value or as
hours:minutes:seconds:hundredths.
This 32-bit MMR configures the mode of operation for Timer2.
Timer2 Value Register
Name
T2VAL
Name
T2CON
Table 112. Timer2 Interface MMRs
T2CON
Access
R
Timer2 Control Register
The Timer2 interface consists of four MMRs, as shown in
Table 112.
T2ICLR
Default Value
0x0000
T2VAL is a 32-bit register that holds the current value of Timer2.
Timer2 reloads the value from T2LD either when Timer2
overflows or immediately after T2ICLR is written.
Name
T2LD
T2VAL
Address
0xFFFF0344
Description
A 32-bit register. Holds 32-bit unsigned integers.
A 32-bit register. Holds 32-bit unsigned integers.
This register is read only.
An 8-bit register. Writing any value to this register
clears the Timer2 interrupt.
The configuration MMR (see Table 113).
Rev. 0 | Page 77 of 92
Address
0xFFFF0348
Default Value
0x0000
Access
R/W
ADuC7128/ADuC7129
Table 113. T2CON MMR Bit Designations
Bit
31:11
10:9
Value
00
01
10
11
8
7
6
5:4
00
01
10
11
3:0
0000
0100
1000
1111
Description
Reserved.
Clock Source Select.
Core Clock (Default).
Internal 32.768 kHz Oscillator.
External 32.768 kHz Watch Crystal.
External 32.768 kHz Watch Crystal.
Count Up.
Set by user for Timer2 to count up.
Cleared by user for Timer2 to count down (default).
Timer2 Enable Bit.
Set by user to enable Timer2.
Cleared by user to disable Timer2 (default).
Timer2 Mode.
Set by user to operate in periodic mode.
Cleared by user to operate in free-running mode (default).
Format.
Binary (Default).
Reserved.
Hours:Minutes:Seconds:Hundredths: 23 Hours to 0 Hours.
Hours:Minutes:Seconds:Hundredths: 255 Hours to 0 Hours.
Prescaler.
Source Clock/1 (Default).
Source Clock/16.
Source Clock/256. This setting should be used in conjunction with Timer2 formats 1,0 and 1,1.
Source Clock/32,768.
Rev. 0 | Page 78 of 92
ADuC7128/ADuC7129
Timer3 is automatically halted during JTAG debug access and
only recommences counting once JTAG has relinquished control
of the ARM7 core. By default, Timer3 continues to count during
power-down. This can be disabled by setting Bit 0 in T3CON. It is
recommended that the default value is used, that is, the watchdog
timer continues to count during power-down.
TIMER3—WATCHDOG TIMER
16-BIT LOAD
PRESCALER
1, 16, OR 256
16-BIT
UP/DOWN
COUNTER
WATCHDOG
RESET
TIMER3IRQ
TIMER3 VALUE
06020-053
LOW POWER
32.768kHz
Figure 58. Timer3 Block Diagram
Timer3 has two modes of operation: normal mode and
watchdog mode. The watchdog timer is used to recover from an
illegal software state. Once enabled, it requires periodic
servicing to prevent it from forcing a reset of the processor.
Timer3 Interface
The Timer3 interface consists of four MMRs, as shown in Table 114.
Table 114. Timer3 Interface MMRs
Name
T3CON
T3LD
T3VAL
Timer3 reloads the value from T3LD either when Timer3
overflows or immediately after T3ICLR is written.
T3ICLR
Normal Mode
The Timer3 in normal mode is identical to Timer0 in 16-bit
mode of operation, except for the clock source. The clock source
is the 32.768 kHz oscillator and can be scaled by a factor of 1,
16, or 256. Timer3 also features a capture facility that allows
capture of the current timer value if the Timer2 interrupt is
enabled via IRQEN[5].
Watchdog Mode
Description
The configuration MMR (see Table 115).
A 16-bit register (Bit 0 to Bit15). Holds 16-bit
unsigned integers.
A 16-bit register (Bit 0 to Bit 15). Holds 16-bit
unsigned integers. This register is read only.
An 8-bit register. Writing any value to this register
clears the Timer3 interrupt in normal mode or resets
a new timeout period in watchdog mode.
Timer3 Load Register
Name
T3LD
Address
0xFFFF0360
Default Value
0x03D7
Access
R/W
This 16-bit MMR holds the Timer3 reload value.
Timer3 Value Register
Watchdog mode is entered by setting T3CON[5]. Timer3 decrements from the timeout value present in the T3LD register to 0.
The maximum timeout is 512 seconds, using the maximum
prescalar/256 and full scale in T3LD.
Name
T3VAL
User software should only configure a minimum timeout
period of 30 ms. This is to avoid any conflict with Flash/EE
memory page erase cycles, which require 20 ms to complete
a single page erase cycle and kernel execution.
Timer3 Clear Register
Once watchdog mode is entered, T3LD and T3CON are write
protected. These two registers cannot be modified until a
power-on reset event resets the watchdog timer. After any other
reset event, the watchdog timer continues to count. The
watchdog timer should be configured in the initial lines of user
code to avoid an infinite loop of watchdog resets.
Default Value
0x03D7
Access
R
This 16-bit, read-only MMR holds the current Timer3 count value.
Name
T3ICLR
If T3VAL reaches 0, a reset or an interrupt occurs, depending
on T3CON[1]. To avoid a reset or an interrupt event, any value
can be written to T3ICLR before T3VAL reaches 0. This reloads
the counter with T3LD and begins a new timeout period.
Address
0xFFFF0364
Address
0xFFFF036C
Default Value
0x00
Access
W
This 8-bit, write-only MMR is written (with any value) by user
code to refresh (reload) Timer3 in watchdog mode to prevent a
watchdog timer reset event.
Timer3 Control Register
Name
T3CON
Address
0xFFFF0368
Default Value
0x00
Access
R/W
once
only
The 16-bit MMR configures the mode of operation of Timer3.
as described in detail in Table 115.
Rev. 0 | Page 79 of 92
ADuC7128/ADuC7129
Table 115. T3CON MMR Bit Designations
Bit
16:9
8
Value
7
6
5
4
3:2
00
01
10
11
1
0
Description
These bits are reserved and should be written as 0s by user code.
Count Up/Down Enable.
Set by user code to configure Timer3 to count up.
Cleared by user code to configure Timer3 to count down.
Timer3 Enable.
Set by user code to enable Timer3.
Cleared by user code to disable Timer3.
Timer3 Operating Mode.
Set by user code to configure Timer3 to operate in periodic mode.
Cleared by user to configure Timer3 to operate in free-running mode.
Watchdog Timer Mode Enable.
Set by user code to enable watchdog mode.
Cleared by user code to disable watchdog mode.
Secure Clear Bit.
Set by user to use the secure clear option.
Cleared by user to disable the secure clear option by default.
Timer3 Clock (32.768 kHz) Prescaler.
Source Clock/1 (Default).
Reserved.
Reserved.
Reserved.
Watchdog Timer IRQ Enable.
Set by user code to produce an IRQ instead of a reset when the watchdog reaches 0.
Cleared by user code to disable the IRQ option.
PD_OFF.
Set by user code to stop Timer3 when the peripherals are powered down via Bit 4 in the POWCON MMR.
Cleared by user code to enable Timer3 when the peripherals are powered down via Bit 4 in the POWCON MMR.
Secure Clear Bit (Watchdog Mode Only)
The secure clear bit is provided for a higher level of protection.
When set, a specific sequential value must be written to T3ICLR
to avoid a watchdog reset. The value is a sequence generated by
the 8-bit linear feedback shift register (LFSR) polynomial equal
to X8 + X6 + X5 + X + 1, as shown in Figure 59.
D
7
Q
D
6
Q
D
5
Q
D
4
Q
D
3
Q
D
2
Q
D
1
Q
D
0
06020-054
Q
CLOCK
Figure 59. 8-Bit LFSR
The value 0x00 should not be used as an initial seed due to the
properties of the polynomial. The value 0x00 is always guaranteed to force an immediate reset. The value of the LFSR cannot
be read; it must be tracked/generated in software.
The following is an example of a sequence:
1.
2.
3.
4.
5.
The initial value or seed is written to T3ICLR before entering
watchdog mode. After entering watchdog mode, a write to
T3ICLR must match this expected value. If it matches, the LFSR
is advanced to the next state when the counter reload happens.
If it fails to match the expected state, reset is immediately
generated, even if the count has not yet expired.
Rev. 0 | Page 80 of 92
Enter initial seed, 0 xAA, in T3ICLR before starting
Timer3 in watchdog mode.
Enter 0 xAA in T3ICLR; Timer3 is reloaded.
Enter 0x37 in T3ICLR; Timer3 is reloaded.
Enter 0x6E in T3ICLR; Timer3 is reloaded.
Enter 0x66. 0xDC was expected; the watchdog resets
the chip.
ADuC7128/ADuC7129
Note that if the part is in a low power mode and Timer4 is clocked
from the GPIO or oscillator source, Timer4 continues to operate.
TIMER4—GENERAL-PURPOSE TIMER
32-BIT LOAD
32.768kHz
OSCILLATOR
CORE CLOCK
FREQUENCY
PRESCALER
1, 16, 256,
OR 32768
GPIO
32-BIT
UP/DOWN COUNTER
Timer4 reloads the value from T4LD either when Timer 4
overflows, or immediately when T4ICLR is written.
TIMER4IRQ
Timer4 Load Register
GPIO
Name
T4LD
IRQ[31:0]
06020-055
TIMER1 VALUE
CAPTURE
Figure 60. Timer4 Block Diagram
Timer4 is a 32-bit, general-purpose count down or count up
timer with a programmable prescalar. The prescalar source
can be the 32 kHz oscillator, the core clock, or one of two external
GPIOs. This source can be scaled by a factor of 1, 16, 256, or
32,768. This gives a minimum resolution of 42 ns when operating
at CD zero, the core is operating at 41.78 MHz, and with a prescalar
of 1 (ignoring external GPIO).
The counter can be formatted as a standard 32-bit value or as
hours:minutes:seconds:hundredths.
Timer4 has a capture register (T4CAP), which can be triggered
by a selected IRQ source initial assertion. Once triggered, the
current timer value is copied to T4CAP, and the timer keeps
running. This feature can be used to determine the assertion of
an event with increased accuracy.
Address
0xFFFF0380
Default Value
0x00000
Access
R/W
T4LD is a 32-bit register that holds the 32-bit value that is
loaded into the counter.
Timer4 Clear Register
Name
T4ICLR
Address
0xFFFF038C
Default Value
0x00
Access
W
This 8-bit, write only MMR is written (with any value) by user
code to refresh (reload) Timer4.
Timer4 Value Register
Name
T4VAL
Address
0xFFFF0384
Default Value
0x0000
Access
R
T4VAL is a 32-bit register that holds the current value of Timer4.
Timer4 Capture Register
Name
T4CAP
Address
0xFFFF0390
Default Value
0x00
Access
R
The Timer4 interface consists of five MMRs.
This is a 32-bit register that holds the 32-bit value captured by
an enabled IRQ event.
Table 116. Timer4 Interface MMRs
Timer4 Control Register
Name
T4LD
T4VAL
Name
T4CON
T4CAP
T4ICLR
T4CON
Description
A 32-bit register. Holds 32-bit unsigned integers.
A 32-bit register. Holds 32-bit unsigned integers.
This register is read only.
A 32-bit register. Holds 32-bit unsigned integers.
This register is read only.
An 8-bit register. Writing any value to this register
clears the Timer1 interrupt.
The configuration MMR (see Table 117).
Address
0xFFFF0388
Default Value
0x0000
Access
R/W
This 32-bit MMR configures the mode of operation of Timer4.
Rev. 0 | Page 81 of 92
ADuC7128/ADuC7129
Table 117. T4CON MMR Bit Designations
Bit
31:18
17
Value
16:12
11:9
000
001
010
011
8
7
6
5:4
00
01
10
11
3:0
0000
0100
1000
1111
Description
Reserved. Set by user to 0.
Event Select Bit.
Set by user to enable time capture of an event.
Cleared by user to disable time capture of an event.
Event Select Range, 0 to 31. The events are as described in the Timers section.
Clock Select.
Core Clock (Default).
32.768 kHz Oscillator.
P4.6.
P4.7.
Count Up.
Set by user for Timer4 to count up.
Cleared by user for Timer4 to count down (default).
Timer4 Enable Bit.
Set by user to enable Timer4.
Cleared by user to disable Timer4 (default).
Timer4 Mode.
Set by user to operate in periodic mode.
Cleared by user to operate in free-running mode (default).
Format.
Binary (Default).
Reserved.
Hours:Minutes:Seconds:Hundredths: 23 Hours to 0 Hours.
Hours:Minutes:Seconds:Hundredths: 255 Hours to 0 Hours.
Prescaler.
Source Clock/1 (Default).
Source Clock/16.
Source Clock/256.
Source Clock/32,768.
Rev. 0 | Page 82 of 92
ADuC7128/ADuC7129
EXTERNAL MEMORY INTERFACING
The ADuC7129 is the only model in the series that features an
external memory interface. The external memory interface requires
a larger number of pins. This is why it is only available on larger
pin count packages. The XMCFG MMR must be set to 1 to use
the external port.
A16
AD15:0
LATCH
The memory interface can address up to four 128 kB regions of
asynchronous memory (SRAM and/or EEPROM).
CS
WS
WE
RS
OE
RAM
128k × 8-BIT
D0 TO D7
A16
A0:15
Table 118. External Memory Interfacing Pins
WE
OE
06020-068
CS
Function
Address/Data Bus.
Extended Addressing for 8-Bit Memory Only.
Memory Select.
Write Strobe.
Read Strobe.
Address Latch Enable.
Byte Write Capability.
Figure 61. Interfacing to External EPROM/RAM
XMCFG Register
Name
XMCFG
There are four external memory regions available, as described
in Table 119. Associated with each region are the MS[3:0] pins.
These signals allow access to the particular region of external
memory. The size of each memory region can be 128 kB
maximum, 64 k × 16, or 128 k × 8. To access 128 kB with an
8-bit memory, an extra address line (A16) is provided. (See the
example in Figure 61). The four regions are configured independently.
Table 119. Memory Regions
Address End
0x1000FFFF
0x2000FFFF
0x3000FFFF
0x4000FFFF
A0:15
MS0
MS1
The pins required for interfacing to an external memory are
shown in Table 118.
Address Start
0x10000000
0x20000000
0x30000000
0x40000000
D0 TO D15
AE
Although 32-bit addresses are supported internally, only the lower
16 bits of the address are on external pins.
Pin
AD[15:0]
A16
MS[3:0]
WR (WR)
RS (RS)
AE
BHE, BLE
EPROM
64k × 16-BIT
ADuC7128/
ADuC7129
Address
0xFFFFF000
Default Value
0x00
Access
R/W
XMCFG is set to 1 to enable external memory access. This must
be set to 1 before any port pins function as external memory
access pins. The port pins must also be individually enabled via
the GPxCON MMR.
XMxCON Registers
Name
XM0CON
XM1CON
XM2CON
XM3CON
Address
0xFFFFF010
0xFFFFF014
0xFFFFF018
0xFFFFF01C
Default Value
0x00
0x00
0x00
0x00
Access
R/W
R/W
R/W
R/W
XMxCON registers are the control registers for each memory
region. They allow the enabling/disabling of a memory region
and control the data bus width of the memory region.
Contents
External Memory 0
External Memory 1
External Memory 2
External Memory 3
Table 120. XMxCON MMR Bit Designations
Each external memory region can be controlled through three
MMRs: XMCFG, XMxCON, and XMxPAR.
Bit
1
0
Description
Data Bus Width Select.
Set by the user to select a 16-bit data bus.
Cleared by the user to select an 8-bit data bus.
Memory Region Enable.
Set by the user to enable memory region.
Cleared by the user to disable the memory region.
XMxPAR Registers
Name
XM0PAR
XM1PAR
XM2PAR
XM3PAR
Rev. 0 | Page 83 of 92
Address
0xFFFFF020
0xFFFFF024
0xFFFFF028
0xFFFFF02C
Default Value
0x70FF
0x70FF
0x70FF
0x70FF
Access
R/W
R/W
R/W
R/W
ADuC7128/ADuC7129
The XMxPAR are registers that define the protocol used for accessing the external memory for each memory region.
Table 121. XMxPAR MMR Bit Designations
Bit
15
Description
Enable Byte Write Strobe. This bit is only used for two,
8-bit memory sharing the same memory region.
Set by user to gate the AD0 output with the WS output. This allows byte write capability without using BHE and BLE signals.
Cleared by user to use BHE and BLE signals.
14:12
11
10
Number of Wait States on the Address Latch Enable Strobe.
Reserved.
Extra Address Hold Time.
Set by the user to disable extra hold time.
Cleared by the user to enable one clock cycle of hold on the address in read and write.
Extra Bus Transition Time on Read.
Set by the user to disable extra bus transition time.
Cleared by the user to enable one extra clock before and after the read select (RS).
9
8
Extra Bus Transition Time on Write.
Set by the user to disable extra bus transition time.
Cleared by the user to enable one extra clock before and after the write select (WS).
7:4
Number of Write Wait States. Select the number of wait states added to the length of the WS pulse. 0x0 is 1 clock cycle; 0xF is 16 clock
cycles (default value).
Number of Read Wait States. Select the number of wait states added to the length of the RS pulse. 0x0 is 1 clock cycle; 0xF is 16 clock
cycles (default value).
3:0
TIMING DIAGRAMS
Figure 62 through Figure 65 show the timing for a read cycle (see Figure 62), a read cycle with address hold and bus turn cycles (see
Figure 63), a write cycle with address hold and write hold cycles (see Figure 64), and a write cycle with wait states (see Figure 65).
HCLK
AD16:0
ADDRESS
DATA
MSx
06020-069
AE
RS
Figure 62. External Memory Read Cycle
Rev. 0 | Page 84 of 92
ADuC7128/ADuC7129
HCLK
AD16:0
ADDRESS
DATA
EXTRA ADDRESS
HOLD TIME
(BIT 10)
MSx
AE
BUS TURN OUT CYCLE
(BIT 9)
BUS TURN OUT CYCLE
(BIT 9)
06020-070
RS
Figure 63. External Memory Read Cycle with Address Hold and Bus Turn Cycles
HCLK
AD16:0
ADDRESS
DATA
EXTRA ADDRESS
HOLD TIME
(BIT 10)
MSx
AE
WRITE HOLD ADDRESS
AND DATA CYCLES
(BIT 8)
WRITE HOLD ADDRESS
AND DATA CYCLES
(BIT 8)
Figure 64. External Memory Write Cycle with Address Hold and Write Hold Cycles
Rev. 0 | Page 85 of 92
06020-071
WS
ADuC7128/ADuC7129
HCLK
AD16:0
ADDRESS
DATA
MSx
AE
1 ADDRESS WAIT STATE
(BIT 14 TO BIT 12)
1 WRITE STROBE WAIT STATE
(BIT 7 TO BIT 4)
Figure 65. External Memory Write Cycle with Wait States
Rev. 0 | Page 86 of 92
06020-072
WS
ADuC7128/ADuC7129
HARDWARE DESIGN CONSIDERATIONS
POWER SUPPLIES
The ADuC7128/ADuC7129 operational power supply voltage
range is 3.0 V to 3.6 V. Separate analog and digital power supply
pins (AVDD and IOVDD, respectively) allow AVDD to be kept
relatively free of noisy digital signals often present on the system
IOVDD line. In this mode, the part can also operate with split
supplies, that is, using different voltage supply levels for each
supply. For example, the system can be designed to operate with
an IOVDD voltage level of 3.3 V while the AVDD level can be at
3 V, or vice versa, if required. A typical split supply configuration
is shown in Figure 66.
ANALOG SUPPLY
10µF
ADuC7128
IOVDD
0.1µF
0.1µF
0.47µF
10µF
+
AVDD
LVDD
PVDD
DACV DD
0.1µF
0.1µF
GNDREF
DACGND
AGND
IOGND
REFGND
06020-056
+
Finally, on the LFCSP package, the paddle on the bottom of the
package should be soldered to a metal plate to provide mechanical
stability. The metal plate should be connected to ground.
Linear Voltage Regulator
The ADuC7128/ADuC7129 require a single 3.3 V supply, but
the core logic requires a 2.5 V supply. An on-chip linear regulator
generates the 2.5 V from IOVDD for the core logic. The LVDD pin
is the 2.5 V supply for the core logic. The DAC logic and PLL logic
also require a 2.5 V supply that must be connected externally from
the LVDD pin to the DACVDD pin and the PVDD pin. An external
compensation capacitor of 0.47 μF must be connected between
LVDD and DGND (as close as possible to these pins) to act as a
tank of charge, as shown in Figure 68. In addition, decoupling
capacitors of 0.1 μF must be placed as close as possible to the
PVDD pin and the DACVDD pin.
ADuC7128
Figure 66. External Dual Supply Connections
As an alternative to providing two separate power supplies, the
user can help keep AVDD quiet by placing a small series resistor
and/or ferrite bead between AVDD and IOVDD, and then decoupling
AVDD separately to ground. An example of this configuration is
shown in Figure 67. With this configuration, other analog circuitry
(such as op amps or voltage references) can be powered from
the AVDD supply line as well.
BEAD
DIGITAL SUPPLY
+
1.6V
10µF
10µF
+
ADuC7128
IOVDD
0.1µF
0.1µF
DACGND
AGND
REFGND
0.1µF
DACV DD
0.47µF
Figure 68. Voltage Regulator Connections
The LVDD pin should not be used for any other chip. It is also
recommended that the IOVDD have excellent power supply
decoupling to help improve line regulation performance of the
on-chip voltage regulator.
As with all high resolution data converters, special attention
must be paid to grounding and PC board layout of the design to
achieve optimum performance from the ADCs and DAC.
GNDREF
IOGND
PVDD
GROUNDING AND BOARD LAYOUT
RECOMMENDATIONS
06020-057
0.47µF
0.1µF
0.1µF
AVDD
LVDD
PVDD
DACV DD
LVDD
06020-058
DIGITAL SUPPLY
Connect the ground terminal of each of these capacitors directly
to the underlying ground plane. It should also be noted that, at
all times, the analog and digital ground pins on the ADuC7128/
ADuC7129 must be referenced to the same system ground reference point.
Figure 67. External Single Supply Connections
Note that in both Figure 66 and Figure 67, a large value (10 μF)
reservoir capacitor sits on IOVDD and a separate 10 μF capacitor
sits on AVDD. In addition, local small value (0.1 μF) capacitors
are located at each AVDD and IOVDD pin of the chip. As per
standard design practice, be sure to include all of these capacitors and ensure that the smaller capacitors are close to each
AVDD pin with trace lengths as short as possible.
Although the ADuC7128/ADuC7129 have separate pins for
analog and digital ground (AGND and IOGND), the user must
not tie these to two separate ground planes unless the two ground
planes are connected together very close to the ADuC7128/
ADuC7129, as illustrated in the simplified example of Figure 69a.
In systems where digital and analog ground planes are connected
together somewhere else (for example, at the system power
supply), they cannot be connected again near the ADuC7128/
ADuC7129 because a ground loop results.
Rev. 0 | Page 87 of 92
ADuC7128/ADuC7129
In these cases, tie the AGND pins and IOGND pins of the
ADuC7128/ADuC7129 to the analog ground plane, as shown
in Figure 69b. In systems with only one ground plane, ensure
that the digital and analog components are physically separated
onto separate halves of the board such that digital return currents
do not flow near analog circuitry and vice versa. The ADuC7128/
ADuC7129 can then be placed between the digital and analog
sections, as illustrated in Figure 69c.
a.
b.
PLACE ANALOG
COMPONENTS HERE
PLACE DIGITAL
COMPONENTS HERE
AGND
DGND
PLACE ANALOG
COMPONENTS
HERE
A value of 100 Ω or 200 Ω is usually sufficient to prevent high
speed signals from coupling capacitively into the ADuC7128/
ADuC7129 and affecting the accuracy of ADC conversions.
CLOCK OSCILLATOR
The clock source for the ADuC7128/ADuC7129 can be generated by the internal PLL or by an external clock input. To use
the internal PLL, connect a 32.768 kHz parallel resonant crystal
between XCLKI and XCLKO as shown Figure 70. External
capacitors should be connected as per the crystal manufacturer’s
recommendations. Note that the crystal pads already have an
internal capacitance of typically 10 pF. Users should ensure that
the total capacitance (10 pF internal + external capacitance)
does not exceed the manufacturer rating.
PLACE DIGITAL
COMPONENTS HERE
AGND
If a user plans to connect fast logic signals (rise/fall time < 5 ns)
to any of the digital inputs of the ADuC7128/ADuC7129, add
a series resistor to each relevant line to keep rise and fall times
longer than 5 ns at the ADuC7128/ADuC7129 input pins.
The 32 kHz crystal allows the PLL to lock correctly to give a
frequency of 41.78 MHz. If no external crystal is present, the
internal oscillator is used to give a frequency of 41.78 MHz ±
3% typically.
DGND
ADuC7128
XCLKO
12pF
PLACE DIGITAL
COMPONENTS HERE
12pF
XCLKI
TO
INTERNAL
PLL
06020-060
GND
32.768kHz
Figure 70. External Parallel Resonant Crystal Connections
Figure 69. System Grounding Schemes
In all of these scenarios, and in more complicated real-life
applications, keep in mind the flow of current from the supplies
and back to ground. Make sure the return paths for all currents
are as close as possible to the paths the currents took to reach
their destinations. For example, do not power components on
the analog side (see Figure 69b) with IOVDD since that would
force return currents from IOVDD to flow through AGND.
Avoid digital currents from flowing under analog circuitry,
which could happen if the user places a noisy digital chip on the
left half of the board (see Figure 69c). Whenever possible, avoid
large discontinuities in the ground planes (such as are formed
by a long trace on the same layer) because they force return
signals to travel a longer path. Make all connections to the ground
plane directly, with little or no trace separating the pin from its
via to ground.
To use an external source clock input instead of the PLL, Bit 1
and Bit 0 of PLLCON must be modified. The external clock
uses the XCLK pin.
ADuC7128
XCLKI
EXTERNAL
CLOCK
SOURCE
XCLK
TO
FREQUENCY
DIVIDER
06020-061
PLACE ANALOG
COMPONENTS HERE
06020-059
c.
Figure 71. Connecting an External Clock Source
Whether using the internal PLL or an external clock source, the
specified operational clock speed range of the ADuC7128/
ADuC7129 is 50 kHz to 41.78 MHz to ensure correct operation
of the analog peripherals and Flash/EE.
Rev. 0 | Page 88 of 92
ADuC7128/ADuC7129
3.3V
POWER-ON RESET OPERATION
IOVDD
2.6V
2.4V TYP
2.4V TYP
LVDD
64ms TYP
POR
0.12ms TYP
06020-062
An internal power-on reset (POR) is implemented on the
ADuC7128/ADuC7129. For LVDD below 2.45 V, the internal
POR holds the ADuC7128/ADuC7129 in reset. As LVDD rises
above 2.45 V, an internal timer times out for typically 64 ms
before the part is released from reset. The user must ensure that
the power supply, IOVDD, has reached a stable 3.0 V minimum
level by this time. On power-down, the internal POR holds the
ADuC7128/ADuC7129 in reset until LVDD has dropped below
2.45 V. Figure 72 illustrates the operation of the internal POR
in detail.
MRST
Figure 72. Internal Power-On Reset Operation
Rev. 0 | Page 89 of 92
ADuC7128/ADuC7129
DEVELOPMENT TOOLS
An entry level, low cost development system is available for the
ADuC7128/ADuC7129. This system consists of the following
PC-based (Windows® compatible) hardware and software
development tools.
IN-CIRCUIT SERIAL DOWNLOADER
The serial downloader is a Windows application that allows the
user to serially download an assembled program to the on-chip
program Flash/EE memory via the serial port on a standard PC.
Hardware
•
•
•
ADuC7128/ADuC7129 evaluation board
Serial port programming cable
JTAG emulator
Software
•
•
•
Integrated development environment, incorporating
assembler, compiler, and nonintrusive JTAG-based
debugger
Serial downloader software
Example code
Miscellaneous
•
CD-ROM documentation
Rev. 0 | Page 90 of 92
ADuC7128/ADuC7129
OUTLINE DIMENSIONS
9.00
BSC SQ
0.60 MAX
64
49
48
PIN 1
INDICATOR
8.75
BSC SQ
*4.85
EXPOSED PAD
4.70 SQ
4.55
(BOTTOM VIEW)
0.50
0.40
0.30
33
32
16
17
7.50
REF
0.80 MAX
0.65 TYP
12° MAX
THE EXPOSE PAD IS NOT CONNECTED
INTERNALLY. FOR INCREASED RELIABILITY
OF THE SOLDER JOINTS AND MAXIMUM
THERMAL CAPABILITY IT IS RECOMMENDED
THAT THE PAD BE SOLDERED TO
THE GROUND PLANE.
0.05 MAX
0.02 NOM
SEATING
PLANE
0.50 BSC
PIN 1
INDICATOR
1
0.20 REF
063006-B
TOP
VIEW
*COMPLIANT TO JEDEC STANDARDS MO-220-VMMD-4
EXCEPT FOR EXPOSED PAD DIMENSION
Figure 73. 64-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
9 mm × 9 mm Body, Very Thin Quad
(CP-64-1)
Dimensions shown in millimeters
0.75
0.60
0.45
12.20
12.00 SQ
11.80
1.60
MAX
64
49
1
48
PIN 1
10.20
10.00 SQ
9.80
TOP VIEW
(PINS DOWN)
1.45
1.40
1.35
0.15
0.05
SEATING
PLANE
VIEW A
0.20
0.09
7°
3.5°
0°
0.08
COPLANARITY
16
33
32
17
VIEW A
0.50
BSC
LEAD PITCH
ROTATED 90° CCW
0.27
0.22
0.17
COMPLIANT TO JEDEC STANDARDS MS-026-BCD
Figure 74. 64-Lead Low Profile Quad Flat Package [LQFP]
(ST-64-2)
Dimensions shown in millimeters
Rev. 0 | Page 91 of 92
051706-A
1.00
0.85
0.80
0.30
0.25
0.18
0.60 MAX
ADuC7128/ADuC7129
0.75
0.60
0.45
14.20
14.00 SQ
13.80
1.60
MAX
80
61
60
1
PIN 1
12.20
12.00 SQ
11.80
TOP VIEW
(PINS DOWN)
0.15
0.05
SEATING
PLANE
0.20
0.09
7°
3.5°
0°
0.08
COPLANARITY
VIEW A
20
41
21
VIEW A
0.50
BSC
LEAD PITCH
ROTATED 90° CCW
40
0.27
0.22
0.17
COMPLIANT TO JEDEC STANDARDS MS-026-BDD
051706-A
1.45
1.40
1.35
Figure 75. 80-Lead Low Profile Quad Flat Package [LQFP]
(ST-80-1)
Dimensions shown in millimeters
ORDERING GUIDE
Model 1
ADUC7128BCPZ126 2
ADUC7128BCPZ126-RL2
ADUC7128BSTZ1262
ADUC7128BSTZ126-RL2
ADUC7129BSTZ1262
ADUC7129BSTZ126-RL2
EVAL-ADUC7128QSPZ2
1
2
Temperature Range
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
Package Description
64-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
64-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
64-Lead LQFP
64-Lead LQFP
80-Lead LQFP
80-Lead LQFP
Evaluation Board
Package Option
CP-64-1
CP-64-1
ST-64-2
ST-64-2
ST-80-1
ST-80-1
Reel quantities are 2,500 for the LFCSP and 1,000 for the LQFP.
Z = RoHS Compliant Part.
Purchase of licensed I2C components of Analog Devices or one of its sublicensed Associated Companies conveys a license for the purchaser 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.
©2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D06020-0-4/07(0)
Rev. 0 | Page 92 of 92

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