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DS5000FPDALLASN/a16avaiSoft Microprocessor Chip


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DS5000FP
Soft Microprocessor Chip
FEATURES � 8051-Compatible Microprocessor Adapts
to Its Task
− Accesses between 8kB and 64kB of
nonvolatile SRAM − In-system programming via on-chip serial
port − Can modify its own program or data
memory − Accesses memory on a separate byte-wide
bus � Crash-Proof Operation − Maintains all nonvolatile resources for
over 10 years − Power-fail Reset − Early Warning Power-fail Interrupt − Watchdog Timer − User-supplied lithium battery backs user
SRAM for program/data storage � Software Security − Executes encrypted programs to prevent
observation − Security lock prevents download − Unlocking destroys contents � Fully 8051 Compatible − 128 bytes scratchpad RAM − Two timer/counters − On-chip serial port − 32 parallel I/O port pins
PIN CONFIGURATION

ORDERING INFORMATION
PART TEMP RANGE MAX CLOCK
SPEED (MHz)
PIN-
PACKAGE

DS5000FP-16 0°C to +70°C 16 80 QFP
DS5000FP-16+ 0°C to +70°C 16 80 QFP
+ Denotes a Pb-free/RoHS-compliant device.
DS5000FP
Soft Microprocessor Chip

This data sheet must be used in conjunction with the Secure
Microcontroller User’s Guide, which contains operating information.
This data sheet provides ordering information, pinout, and electrical
specifications. Download the Secure Microcontroller User’s Guide
at /microcontrollers.
10
11
12
13
14
15
16
17
18
19
20
21
22
23
P0.4/AD4
N.C.
N.C.
BA9
P0.3/AD3
BA8
P0.2/AD2
BA13
P0.1/AD1
R/W
P0.0/AD0
VCC0
VCC
VCC
P1.0
BA14
P1.1
BA12
P1.2
BA7
P1.3
N.C.
N.C.
BA6
P2.6/A14
N.C.
N.C.
BD3
P2.5/A13
BD2
P2.4/A12
BD1
P2.3/A11
BD0
VLI
GND
GND
P2.2/A10
P2.1/A9
P2.0/A8
XTAL1
XTAL2
P3.7/RD
P3.6/WR
P3.5/T1
N.C.
N.C.
P3.4/T0
BA11
P1.4
25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65
P0.5/AD5
BA5
CE2
P1.5
P0.6/AD6
BA4
BA10
P1.6
P0.7/AD7
BA3
CE1
P1.7
EA
N.C.
N.C.
BA2
BD7
RST
LE
BA1
BD6
P3.0/RXD
PSEN
BA0
BD5
P3.1/TXD
P2.7/A15
P3.2/INT0
BD4
P3.3/INT1
DS5000FP

TOP VIEW
QFP
DS5000FP
DESCRIPTION

The DS5000FP Soft Microprocessor Chip is an 8051-compatible processor based on NV RAM
technology. It is substantially more flexible than a standard 8051, yet provides full compatibility with the
8051 instruction set, timers, serial port, and parallel I/O ports. By using NV RAM instead of ROM, the
user can program and then reprogram the microcontroller while in-system. The application software can
even change its own operation, which allows frequent software upgrades, adaptive programs, customized
systems, etc. In addition, by using NV SRAM, the DS5000FP is ideal for data-logging applications and it
connects easily to a Dallas real-time clock for time stamp and date.
The DS5000FP provides the benefits of NV RAM without using I/O resources. It uses a nonmultiplexed
byte-wide address and data bus for memory access. This bus can perform all memory access and provides
decoded chip enables for SRAM. This leaves the 32 I/O port pins free for application use. The DS5000FP
uses ordinary SRAM and battery backs the memory contents with a user’s external lithium cell. Data is
maintained for over 10 years with a very small lithium cell. A DS5000FP also provides crash-proof
operation in portable systems or systems with unreliable power. These features include the ability to save
the operating state, Power-fail Reset, Power-fail Interrupt, and Watchdog Timer.
A user loads programs into the DS5000FP via its on-chip Serial Bootstrap Loader. This function
supervises the loading of code into NV RAM, validates it, and then becomes transparent to the user.
Software can be stored in an 8-kbyte or 32-kbyte CMOS SRAM. Using its internal Partitioning, the
DS5000FP will divide this common RAM into user programmable code and data segments. This
Partition can be selected at program loading time, but can be modified anytime later. It will decode
memory access to the SRAM, communicate via its byte-wide bus and write-protect the memory portion
designated as ROM. Combining program and data storage in one device saves board space and cost. The
DS5000FP can also access a second 32 kbytes of NV RAM but this area is restricted to data memory. The
DS2250(T) and DS5000(T) are available for a user who wants a pre-constructed module using the
DS5000FP, RAM, lithium cell, and optional real-time clock. Each device is described in separate data
sheets, available on our website at /microcontrollers. More details are contained in
the Secure Microcontroller User’s Guide.
DS5000FP
DS5000FP BLOCK DIAGRAM Figure 1

DS5000FP
PIN DESCRIPTION
PIN NAME FUNCTION

15, 17, 19, 21,
25, 27, 29, 31 P1.0–P1.7 General-Purpose I/O Port 1
34 RST Active-High Reset Input. A logic 1 applied to this pin activates a reset state. This
pin is pulled down internally so this pin can be left unconnected if not used.
36 P3.0/
RXD
General-Purpose I/O Port Pin 3.0. Also serves as the receive signal for the on

board UART. This pin should not be connected directly to a PC COM port.
38 P3.1/
TXD
General-Purpose I/O Port Pin 3.1. Also serves as the transmit signal for the on-

board UART. This pin should not be connected directly to a PC COM port.
39 P3.2/
INT0
General-Purpose I/O Port Pin 3.2. Also serves as the active-low External

Interrupt 0.
40 P3.3/
INT1
General-Purpose I/O Port Pin 3.3. Also serves as the active-low External

Interrupt 1.
41 P3.4/T0 General-Purpose I/O Port Pin 3.4. Also serves as the Timer 0 input.
44 P3.5/T1 General-Purpose I/O Port Pin 3.5. Also serves as the Timer 1 input.
45 P3.6/WR General-Purpose I/O Port Pin. Also serves as the write strobe for expanded bus
operation.
46 P3.7/RD General-Purpose I/O Port Pin. Also serves as the read strobe for expanded bus
operation.
47, 48 XTAL2,
XTAL1
Crystal Connections. Used to connect an external crystal to the internal

oscillator. XTAL1 is the input to an inverting amplifier and XTAL2 is the output.
52, 53 GND Logic Ground
49, 50, 51, 56,
58, 60, 64, 66 P2.0–P2.7 General-Purpose I/O Port 2. Also serves as the MSB of the expanded address
bus.
68 PSEN
Program Store Enable. This active-low signal is used to enable an external

program memory when using the expanded bus. It is normally an output and
should be unconnected if not used. PSEN is also used to invoke the Bootstrap
Loader. At this time, PSEN will be pulled down externally. This should only be
done once the DS5000FP is already in a reset state. The device that pulls down
should be open drain since it must not interfere with PSEN under normal
operation.
70 ALE
Address Latch Enable. Used to de-multiplex the multiplexed Expanded

Address/Data bus on Port 0. This pin is normally connected to the clock input on a
’373 type transparent latch. When using a parallel programmer, this pin also
assumes the PROG function for programming pulses.
73 EA
External Access. This pin forces the DS5000FP to behave like an 8031. No

internal memory (or clock) will be available when this pin is at a logic low. Since
this pin is pulled down internally, it should be connected to +5V to use NV RAM.
In a parallel programmer, this pin also serves as VPP for super voltage pulses.
DS5000FP
PIN DESCRIPTION (continued)
PIN NAME FUNCTION

11, 9, 7, 5, 1,
79, 77, 75 P0.0–P0.7
General-Purpose I/O Port 0. This port is open-drain and cannot drive a logic 1.

It requires external pullups. Port 0 is also the multiplexed Expanded Address/Data
bus. When used in this mode, it does not require pullups.
13, 14 VCC Power Supply, +5V
16, 8, 18, 80,
76, 4, 6, 20, 24,
26, 28, 30, 33,
35, 37
BA14–
BA0
Byte-Wide Address Bus Bits 14–0. This 15-bit bus is combined with the

nonmultiplexed data bus (BD7–BD0) to access NV SRAM. Decoding is
performed on CE1 and CE2. Read/write access is controlled by R/W. BA14–BA0
connect directly to an 8k or 32k SRAM. If an 8k RAM is used, BA13 and BA14
are unconnected. Note: BA13 and BA14 are inverted from the true logical address.
BA14 is lithium backed.
71, 69, 67, 65,
61, 59, 57, 55 BD7–BD0
Byte-Wide Data Bus Bits 7–0. This 8-bit bidirectional bus is combined with the

nonmultiplexed address bus (BA14–BA0) to access NV SRAM. Decoding is
performed on CE1 and CE2. Read/write access is controlled by R/W. BD7–BD0
connect directly to an 8k or 32k SRAM, and optionally to a real-time clock.
10 R/W
Read/Write (Active Low). This signal provides the write enable to the SRAMs

on the byte-wide bus. It is controlled by the memory map and partition. The
blocks selected as Program (ROM) is write protected.
74 CE1
Active-Low Chip Enable 1. This is the primary decoded chip enable for memory

access on the byte-wide bus. It connects to the chip enable input of one SRAM.
CE1 is lithium backed. It will remain in a logic high inactive state when VCC falls
below VLI.
78 CE2
Active-Low Chip Enable 2. This chip enable is provided to bank switch to a

second block of 32k bytes of nonvolatile data memory. It connects to the chip
enable input of one SRAM or one lithium-backed peripheral such a real-time
clock. CE2 is lithium backed. It will remain in a logic high inactive state when
VCC falls below VLI.
12 VCCO
VCC Output. This is switched between VCC and VLI by internal circuits based on

the level of VCC. When power is above the lithium input, power will be drawn
from VCC. The lithium cell remains isolated from a load. When VCC is below VLI,
the VCCO switches to the VLI source. VCCO is connected to the VCC pin of an
SRAM.
54 VLI Lithium Voltage Input. Connect to a lithium cell greater than VLImin and no
greater than VLImax as shown in the electrical specifications. Nominal value is +3V.
2, 3, 22, 23, 32,
42, 43, 62, 63,
72
N.C. No Connection. Do not connect.
DS5000FP
INSTRUCTION SET

The DS5000FP executes an instruction set that is object code compatible with the industry standard 8051
microcontroller. As a result, software development packages such as assemblers and compilers that have
been written for the 8051 are compatible with the DS5000FP. A complete description of the instruction
set and operation are provided in the Secure Microcontroller User’s Guide.
Also note that the DS5000FP is embodied in the DS5000(T) and DS2250(T) modules. The DS5000(T)
combines the DS5000FP with one SRAM of either 8 or 32 kbytes and a lithium cell. An optional Real
Time Clock is also available in the DS5000T. This is packaged in a 40-pin DIP module. The DS2250(T)
is an identical function in a SIMM form factor. It also offers the option of a second 32k SRAM mapped
as data on Chip Enable 2.
MEMORY ORGANIZATION

Figure 2 illustrates the memory map accessed by the DS5000FP. The entire 64k of program and 64k of
data is available. The DS5000FP maps 32k of this space into the SRAM connected to the byte-wide bus.
This is the area from 0000h to 7FFFh (32k) and is reached via CE1. Any area not mapped into the NV
RAM is reached via the Expanded bus on Ports 0 & 2. Selecting CE2 provides another 32k of potential
data storage. When CE2 is used, no data is available on the ports. The memory map is covered in detail in
the Secure Microcontroller User’s Guide.
Figure 3 illustrates a typical memory connection for a system using 8k bytes of SRAM. Figure 4 shows a
similar system with 32 kbytes. The byte-wide Address bus connects to the SRAM address lines. The bi-
directional byte-wide data bus connects the data I/O lines of the SRAM. CE1 provides the chip enable
and R/W is the write enable. An additional RAM could be connected to CE2, with common connections
for R/W, BA14-0, and BD7-0.
DS5000FP
POWER MANAGEMENT

The DS5000FP monitors power to provide Power-Fail Reset, early warning Power-Fail Interrupt, and
switchover to lithium backup. It uses the lithium cell at VLI as a reference in determining the switch
points. These are called VPFW, VCCMIN, and VLI respectively. When VCC drops below VPFW, the DS5000FP
will perform an interrupt vector to location 2Bh if the power-fail warning was enabled. Full processor
operation continues regardless. When power falls further to VCCMIN, the DS5000FP invokes a reset state.
No further code execution will be performed unless power rises back above VCCMIN. CE1, CE2, R/W go
to an inactive (logic 1) state. Any address lines that are high (due to encryption) will follow VCC, except
for BA14, which is lithium backed. VCC is still the power source at this time. When VCC drops further to
below VLI, internal circuitry will switch to the lithium cell for power. The majority of internal circuits will
be disabled and the remaining nonvolatile states will be retained. The lithium cell will power any devices
connected to VCCO at this time. VCCO will be at the lithium battery voltage less a diode drop. This drop
will vary depending on the load. Low-leakage SRAMs should be used for this reason. When a module is
used, the lithium cell is selected by Dallas so absolute specifications are provided for the switch
thresholds. When using the DS5000FP, the user must select the appropriate battery. The following
formulas apply to the switch function:
VPFW = 1.45 x VLI
VCCMIN = 1.40 x VLI
VLI Switch = 1.0 x VLI
MEMORY MAP OF THE DS5000FP Figure 2

DS5000FP
DS5000FP CONNECTION TO 8k X 8 SRAM Figure 3

DS5000FP CONNECTION TO 32k X 8 SRAM Figure 4
DS5000FP
ABSOLUTE MAXIMUM RATINGS

Voltage Range on Any Pin Relative to Ground……………………………………...………-0.3V to + (VCC + 0.5V)
Voltage Range on VCC Relative to Ground…………………….……….……………………..………-0.3V to +7.0V
Operating Temperature Range………………………………….….………………………………..…..0°C to +70°C
Storage Temperature Range……………………………………...………………………………..…..-40°C to +70°C
Soldering Temperature Range……………………………………………..See IPC/JEDEC J-STD-020 Specification
This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operation
sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time can affect reliability.
DC CHARACTERISTICS

(VCC = 5V 5%, TA = 0C to +70C.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES

Input Low Voltage VIL -0.3 0.8 V 1
Input High Voltage VIH1 2.0 VCC +0.3 V 1
Input High Voltage RST, XTAL1 VIH2 3.5 VCC + 0.3 V 1
Output Low Voltage
at IOL = 1.6mA (Ports 1, 2, 3) VOL1 0.15 0.45 V
Output Low Voltage
at IOL = 3.2mA (Ports 0, ALE, PSEN,
BA14–BA0, BD7–BD0, R/W, CE1-2)
VOL2 0.15 0.45 V 1
Output High Voltage
at IOH = -80A (Ports 1, 2, 3) VOH1 2.4 4.8 V 1
Output High Voltage
at IOH = -400A (Ports 0, ALE, PSEN,
BA14–BA0, BD7–BD0, R/W, CE1-2)
VOH2 2.4 4.8 V 1
Input Low Current VIN = 0.45V
(Ports 1, 2, 3) IIL -50 A
Transition Current; 1 to 0
VIN = 2.0V (Ports 1, 2, 3) ITL -500 A
Input Leakage Current
0.45 < VIN < VCC (Port 0) IL 10 A
RST, EA Pulldown Resistor RRE 40 125 k
Stop Mode Current ISM 80 A 4
Power-Fail Warning Voltage VPFW 4.15 4.6 4.75 V 1, 6
Minimum Operating Voltage VCCmin 4.05 4.5 4.65 V 1, 6
Operating Voltage VCC VCC(MIN) 5.5 V 1, 6
Lithium Supply Voltage VLI 2.9 3.3 V 1
Programming Supply Voltage
(Parallel Program Mode) VPP 12.5 13 V 1
Program Supply Current IPP 15 20 mA
DS5000FP
DC CHARACTERISTICS (continued)

(VCC = 5V 5%, TA = 0°C to +70°C.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES

Operating Current at 16MHz ICC 36 mA 2
Idle Mode Current at 12MHz IIDLE 6.2 mA 3
Output Supply Voltage VCCO1 VCC - 0.3 V 1
Output Supply Voltage
(Battery-Backed Mode) VCCO2 VLI - 0.65 VLI - 0.5 V 8
Output Supply Current
at VCCO = VCC - 0.3V ICCO1 80 mA 2
Battery-Backed Quiescent Current ILI 5 75 nA 7
NOTES:

1. All voltages are referenced to ground.
2. Maximum operating ICC is measured with all output pins disconnected; XTAL1 driven with tCLKR,
tCLKF = 10ns, VIL = 0.5V; XTAL2 disconnected; EA = RST = PORT0 = VCC.
3. Idle mode ICC is measured with all output pins disconnected; XTAL1 driven at 12MHz with tCLKR,
tCLKF = 10ns, VIL = 0.5V; XTAL2 disconnected; EA = PORT0 = VCC, RST = VSS.
4. Stop mode ICC is measured with all output pins disconnected; EA = PORT0 = VCC; XTAL2 not
connected; RST = VSS.
5. Crystal startup time is the time required to get the mass of the crystal into vibrational motion from the
time that power is first applied to the circuit until the first clock pulse is produced by the on-chip
oscillator. The user should check with the crystal vendor for the worst-case spec on this time.
6. Assumes VLI = 3.3V maximum.
7. ILI is the current drawn from VLI when VCC = 0V and VCCO is disconnected.
8. I CCO = 10A.
AC CHARACTERISTICS: EXPANDED BUS MODE TIMING SPECIFICATIONS
(VCC = 5V 5%, TA = 0C to +70C.)
# PARAMETER SYMBOL MIN

1 Oscillator Frequency 1/tCLK 1.0 16
2 ALE Pulse Width tALPW 2tCLK -40 Address Valid to ALE Low tAVALL tCLK -40 Address Hold After ALE Low tAVAAV tCLK -35
at 12MHz 5 ALE Low to Valid Instruction In at 16MHz tALLVI 4tCLK -90 ALE Low to PSEN Low tALLPSL tCLK -25 ns PSEN Pulse Width tPSPW 3tCLK -35 ns
at 12MHz 3tCLK -150 8 PSEN Low to Valid Instruction In at 16MHz tPSLVI 3tCLK -90 ns Input Instruction Hold after PSEN Going High tPSIV 0 ns
10 Input Instruction Float after PSEN Going High tPSIX tCLK -20 ns
11 Address Hold after PSEN Going High tPSAV tCLK -8 ns
at 12MHz 5tCLK -150 12 Address Valid to Valid
Instruction In at 16MHz tAVVI 5tCLK -90 ns
13 PSEN Low to Address Float tPSLAZ 0 ns
14 RD Pulse Width tRDPW 6tCLK -100 ns
15 WR Pulse Width tWRPW 6tCLK -100 ns
at 12MHz 5tCLK -165 16 RD Low to Valid Data In at 16MHz tRDLDV 5tCLK -105 ns
17 Data Hold after RD High tRDHDV 0 ns
18 Data Float after RD High tRDHDZ 2tCLK -70 ns
at 12MHz 8CLK -150 19 ALE Low to Valid Data In at 16MHz tALLVD 8tCLK -90 ns
at 12MHz 9tCLK -165 20 Valid Address to Valid Data In at 16MHz tAVDV 9tCLK -105 ns
21 ALE Low to RD or WR Low tALLRDL 3tCLK -50 3tCLK +50 ns
22 Address Valid to RD or WR Low tAVRDL 4tCLK -130 ns
23 Data Valid to WR Going Low tDVWRL tCLK -60 ns
at 12MHz 7tCLK -150 24 Data Valid to WR High at 16MHz tDVWRH 7tCLK -90 ns
25 Data Valid after WR High tWRHDV tCLK -50 ns
26 RD Low to Address Float tRDLAZ 0 ns
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