MOTOROLA Order this document by: DSP56002/D, Rev. 3 SEMICONDUCTOR TECHNICAL DATA DSP56002 24-BIT DIGITAL SIGNAL PROCESSOR The DSP56002 is a MPU-style general purpose Digital Signal Processor (DSP) composed of an efficient 24-bit DSP core, program and data memories, various peripherals, and support circuitry. The DSP56000 core is fed by on-chip Program RAM, and two independent data RAMs. The DSP56002 contains a Serial Communication Interface (SCI), Synchronous Serial Interface (SSI), parallel Host Interface (HI), Timer/Event Counter, Phase Lock Loop (PLL), and an On-Chip Emulation (OnCE™) port. This combination of features, illustrated in Figure 1, makes the DSP56002 a cost-effective, high-performance solution for high-precision general purpose digital signal processing. 1 6 24-bit Timer/ Event Counter Sync. Serial (SSI) or I/O 3 Serial Comm. (SCI) or I/O XAB YAB External Data Bus Switch PDB XDB YDB Interrupt Control Clock Gen. Program Decode Controller Program Address Generator Y Data Memory 256 × 24 RAM 256 × 24 ROM (sine) External Address Bus Switch GDB OnCE™ Port 7 X Data Memory 256 × 24 RAM 256 × 24 ROM (A-law/ µ-law) PAB Internal Data Bus Switch PLL Program Memory 512 × 24 RAM 64 × 24 ROM (boot) Host Interface (HI) or I/O Address Generation Unit 24-bit 56000 DSP Core 16-bit Bus 24-bit Bus 15 Data ALU 24 × 24 + 56 → 56-bit MAC Two 56-bit Accumulators Bus Control Address 16 Data 24 Control 10 Program Control Unit 4 3 IRQ AA0604 Figure 1 DSP56002 Block Diagram ©1996 MOTOROLA, INC. SECTION 1 PIN DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 SECTION 2 SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1 SECTION 3 PACKAGING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1 SECTION 4 DESIGN CONSIDERATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1 SECTION 5 ORDERING INFORMATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1 FOR TECHNICAL ASSISTANCE: Telephone: 1 (800) 521-6274 Email: [email protected] Internet: http://www.motorola-dsp.com Data Sheet Conventions This data sheet uses the following conventions: OVERBAR Used to indicate a signal that is active when pulled low (For example, the RESET pin is active when low.) “asserted” Means that a high true (active high) signal is high or that a low true (active low) signal is low “deasserted” Means that a high true (active high) signal is low or that a low true (active low) signal is high Examples: Note: ii Signal/Symbol Logic State Signal State Voltage1 PIN True Asserted VIL/VOL PIN False Deasserted VIH/VOH PIN True Asserted VIH/VOH PIN False Deasserted VIL/VOL Values for VIL, VOL, VIH, and VOH are defined by individual product specifications. DSP56002/D, Rev. 3 MOTOROLA DSP56002 Features FEATURES Digital Signal Processing Core • Efficient 24-bit DSP56000 core • Up to 40 Million Instructions Per Second (MIPS), 25 ns instruction cycle at 80 MHz; up to 33 MIPS, 30.3 ns instruction cycle at 66 MHz • Up to 240 Million Operations Per Second (MOPS) at 80 MHz; up to 198 MOPS at 66 MHz • Performs a 1024-point complex Fast Fourier Transform (FFT) in 59,898 clocks • Highly parallel instruction set with unique DSP addressing modes • Two 56-bit accumulators including extension bits • Parallel 24 × 24-bit multiply-accumulate in 1 instruction cycle (2 clock cycles) • Double precision 48 × 48-bit multiply with 96-bit result in 6 instruction cycles • 56-bit addition/subtraction in 1 instruction cycle • Fractional and integer arithmetic with support for multiprecision arithmetic • Hardware support for block-floating point FFT • Hardware nested DO loops • Zero-overhead fast interrupts (2 instruction cycles) • Four 24-bit internal data buses and three 16-bit internal address buses for maximum information transfer on-chip • On-chip Harvard architecture permitting simultaneous accesses to program and two data memories • 512 × 24-bit on-chip Program RAM and 64 × 24-bit bootstrap ROM • Two 256 × 24-bit on-chip data RAMs • Two 256 × 24-bit on-chip data ROMs containing sine, A-law, and µ-law tables • External memory expansion with 16-bit address and 24-bit data buses • Bootstrap loading from external data bus, Host Interface, or Serial Communications Interface Memory MOTOROLA DSP56002/D, Rev. 3 iii Features Peripheral and Support Circuits • Byte-wide host interface (HI) with Direct Memory Access (DMA) support (or fifteen Port B GPIO lines) • SSI support: – Supports serial devices with one or more industry-standard codecs, other DSPs, microprocessors, and Motorola-SPI-compliant peripherals – Asynchronous or synchronous transmit and receive sections with separate or shared internal/external clocks and frame syncs – Network mode using frame sync and up to 32 software-selectable time slots – 8-bit, 12-bit, 16-bit, and 24-bit data word lengths • SCI for full duplex asynchronous communications (or three additional Port C GPIO lines) • One 24-bit timer/event counter (or one additional GPIO line) • Double-buffered peripherals • Up to twenty-five General Purpose Input/Output (GPIO) pins • One non-maskable and two maskable external interrupt/mode control pins • On-Chip Emulation (OnCE) port for unobtrusive, processor speedindependent debugging • Software-programmable, Phase Lock Loop-based (PLL) frequency synthesizer for the DSP core clock with a wide input frequency range (12.2 KHz to 80 MHz) Miscellaneous Features iv • Power-saving Wait and Stop modes • Fully static, HCMOS design for specified operating frequency down to dc • Three packages available: – 132-pin Plastic Quad Flat Pack (PQFP); 1.1 × 1.1 × 0.19 inches – 144-pin Thin Quad Flat Pack (TQFP); 20 × 20 × 1.5 mm – 132-pin Ceramic Pin Grid Array (PGA); 1.36 × 1.35 × 0.125 inches DSP56002/D, Rev. 3 MOTOROLA DSP56002 Product Documentation PRODUCT DOCUMENTATION The three documents listed in the following table are required for a complete description of the DSP56002 and are necessary to design properly with the part. Documentation is available from one of the following locations (see back cover for detailed information): • A local Motorola distributor • A Motorola semiconductor sales office • A Motorola Literature Distribution Center • The World Wide Web (WWW) Table 1 DSP56002 Documentation Name Description Order Number DSP56000 Family Manual Detailed description of the DSP56000 family processor core and instruction set DSP56KFAMUM/AD DSP56002 User’s Manual Detailed functional description of the DSP56002 memory configuration, operation, and register programming DSP56002UM/AD DSP56002 Technical Data DSP56002 features list and physical, electrical, timing, and package specifications DSP56002/D MOTOROLA DSP56002/D, Rev. 3 v Product Documentation vi DSP56002/D, Rev. 3 MOTOROLA SECTION 1 SIGNAL/PIN DESCRIPTIONS INTRODUCTION DSP56002 signals are organized into twelve functional groups, as summarized in Table 1-1. Table 1-1 Signal Functional Group Allocations Number of Signals Detailed Description Power (VCCX) 16 Table 1-2 Ground (GNDX) 24 Table 1-3 PLL and Clock 7 Table 1-4 Address Bus 16 Table 1-5 24 Table 1-6 Bus Control 10 Table 1-7 Interrupt and Mode Control 4 Table 1-8 15 Table 1-9 3 Table 1-10 Synchronous Serial Interface (SSI) Port 6 Table 1-11 Timer/Event Counter or General Purpose Input/Output (GPIO) 1 Table 1-12 On-Chip Emulation (OnCE) Port 4 Table 1-13 Functional Group Port A1 Data Bus Port B2 Host Interface (HI) Port Serial Communications Interface (SCI) Port Note: 1. 2. 3. Port C3 Port A signals define the External Memory Interface port. Port B signals are the HI signals multiplexed on the external pins with the GPIO signals. Port C signals are the SCI and SSI signals multiplexed on the external pins with the GPIO signals. Figure 1-1 is a diagram of DSP56002 signals by functional group. MOTOROLA DSP56002/D, Rev. 3 1-1 Signal/Pin Descriptions Introduction DSP56002 VCCP VCCCK VCCQ VCCA VCCD VCCC VCCH VCCS GNDP GNDCK GNDQ GNDA GNDD GNDC GNDH GNDS 4 3 3 2 4 5 6 4 2 EXTAL XTAL CKOUT CKP PCAP PINIT PLOCK A0–A15 D0–D23 PS DS X/Y BS BR BG BN WT RD WR Note: Power Inputs: PLL Clock Output Internal Logic Address Bus Data Bus Bus Control HI SSI/SCI Grounds: PLL Clock Internal Logic Address Bus Data Bus Bus Control HI SSI/SCI Interrupt Port B Host Interface (HI) Port1 H0–H7 HA0–HA2 HR/W HEN HREQ HACK PB0–PB7 PB8–PB10 PB11 PB12 PB13 PB14 Port C Synchronous Serial Interface (SSI) Port2 24 8 3 Serial Communications Interface (SCI) Port2 PLL and Clock 16 MODA MODB MODC RESET Interrupt/ Mode Control IRQA IRQB NMI 3 RXD TXD SCLK PC0 PC1 PC2 SC0–SC2 SCK SRD STD PC3–PC5 PC6 PC7 PC8 External Address Bus External Data Bus External Bus Control Timer/ Event Counter TIO Status OnCE Port DSCK DSI DSO DR OS1 OS0 1. The Host Interface port signals are multiplexed with the Port B GPIO signals (PB0–PB15). 2. The SCI and SSI signals are multiplexed with the Port C GPIO signals (PC0–PC8). 3. Power and Ground lines are indicated for the 144-pin TQFP package. AA1081G Figure 1-1 Signals Identified by Functional Group 1-2 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Power POWER Table 1-2 Power Power Names Description VCCP Analog PLL Circuit Power—This line is dedicated to the analog PLL circuits and must remain noise-free to ensure stable PLL frequency and performance. Ensure that the input voltage to this line is well-regulated and uses an extremely low impedance path to tie to the VCC power rail. Use a 0.1 µF capacitor and a 0.01 µF capacitor located as close as possible to the chip package to connect between the VCCP line and the GNDP line. VCCCK Clock Output Power—This line supplies a quiet power source for the CKOUT output. Ensure that the input voltage to this line is well-regulated and uses an extremely low impedance path to tie to the VCC power rail. Use a 0.1 µF bypass capacitor located as close as possible to the chip package to connect between the VCCCK line and the GNDCK line. VCCQ (4) Oscillator Power—These lines supply a quiet power source to the oscillator circuits and the mode control and interrupt lines. Ensure that the input voltage to this line is well-regulated and uses an extremely low impedance path to tie to the VCC power rail. Use a 0.1 µF bypass capacitor located as close as possible to the chip package to connect between the VCCQ lines and the GNDQ lines. VCCA (3) Address Bus Power—These lines supply power to the address bus. VCCD (3) Data Bus Power—These lines supply power to the data bus. VCCC Bus Control Power—This line supplies power to the bus control logic. VCCH (2) Host Interface Power—These lines supply power to the Host Interface logic. VCCS Serial Interface Power—This line supplies power to the serial interface logic (SCI and SSI). MOTOROLA DSP56002/D, Rev. 3 1-3 Signal/Pin Descriptions Ground GROUND Table 1-3 Ground Ground Names Description GNDP Analog PLL Circuit Ground—This line supplies a dedicated quiet ground connection for the analog PLL circuits and must remain relatively noise-free to ensure stable PLL frequency and performance. Ensure that this line connects through an extremely low impedance path to ground. Use a 0.1 µF capacitor and a 0.01 µF capacitor located as close as possible to the chip package to connect between the VCCP line and the GNDP line. GNDCK Clock Output Ground—This line supplies a quiet ground connection for the CKOUT output. Ensure that this line connects through an extremely low impedance path to ground. Use a 0.1 µF bypass capacitor located as close as possible to the chip package to connect between the VCCCK line and the GNDCK line. GNDQ (4) Oscillator Ground—These lines supply a quiet ground connection for the oscillator circuits and the mode control and interrupt lines. Ensure that this line connects through an extremely low impedance path to ground. Use a 0.1 µF bypass capacitor located as close as possible to the chip package to connect between the VCCQ line and the GNDQ line. GNDA (5) Address Bus Ground—These lines connect system ground to the address bus. GNDD (6) Data Bus Ground—These lines connect system ground to the data bus. GNDC Bus Control Ground—This line connects ground to the bus control logic. GNDΗ (4) Host Interface Ground—These lines supply ground connections for the Host Interface logic. GNDS (2) Serial Interface Ground—These lines supply ground connections for the serial interface logic (SCI and SSI). 1-4 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions PLL and Clock PLL AND CLOCK Table 1-4 PLL and Clock Signals Signal Type State during Reset Input Input External Clock/Crystal Input—This input connects the internal oscillator input to an external crystal or to an external oscillator. XTAL Output Chipdriven Crystal Output—This output connects the internal crystal oscillator output to an external crystal. If an external oscillator is used, XTAL should be left unconnected. CKOUT Output Chipdriven PLL Output Clock—When the PLL is enabled and locked, this signal provides a 50% duty cycle output clock signal synchronized to the internal processor clock. Signal Name EXTAL Signal Description When the PLL is enabled and the Multiplication Factor is less than or equal to 4, then CKOUT is synchronized to EXTAL. When the PLL is disabled, the output clock at CKOUT is derived from, and has the same frequency and duty cycle as, EXTAL. Note: CKP PCAP For information about using the PLL Multiplication Factor, see the DSP56002 User’s Manual. Input Input PLL Output Clock Polarity Control—The value of this signal at reset defines the polarity of the CKOUT output relative to EXTAL. If CKP is pulled low by connecting through a resistor to ground, CKOUT and EXTAL have the same polarity. Pulling CKP high by connecting it through a resistor to VCC causes CKOUT and EXTAL to be inverse polarities. The polarity of CKOUT is latched at the end of reset; therefore, any changes to CKP after deassertion of RESET do not affect CKOUT polarity. Input/ Output Indeterminate PLL Capacitor—This signal is used to connect the required external filter capacitor to the PLL filter. Connect one end of the capacitor to PCAP and the other to VCCP. The value of the capacitor is specified in Section 2 of this data sheet. MOTOROLA DSP56002/D, Rev. 3 1-5 Signal/Pin Descriptions PLL and Clock Table 1-4 PLL and Clock Signals (Continued) Signal Name PINIT Signal Type State during Reset Input Input Signal Description PLL Initialization Source—The value of this signal at reset defines the value written into the PLL Enable (PEN) bit in the PLL control register. If PINIT is pulled high during reset, the PEN bit is written as a 1, enabling the PLL and causing the DSP internal clocks to be derived from the PLL VCO. If PINIT is pulled low during reset, the PEN bit is written as a 0, disabling the PLL and causing DSP internal clocks to be derived from the clock connected to EXTAL. PEN is written only at the deassertion of RESET and; therefore, the value of PINIT is ignored after that time. PLOCK Output Indeterminate Phase and Frequency Lock—This output is generated by an internal Phase Detector circuit. This circuit drives the output high when: • the PLL is disabled (the output clock is EXTAL and is therefore in phase with itself), or • the PLL is enabled and is locked onto the proper phase (based on the CKP value) and frequency of EXTAL. The circuit drives the output low (deasserted) whenever the PLL is enabled, but has not locked onto the proper phase and frequency. Note: 1-6 PLOCK is a reliable indicator of the PLL lock state only after the chip has exited the Reset state. During hardware reset, the PLOCK state is determined by PINIT and the current PLL lock condition. DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Address Bus ADDRESS BUS Table 1-5 Address Bus Signals Signal Names Signal Type A0–A15 Output State during Reset Signal Description Tri-stated Address Bus—These signals specify the address for external program and data memory accesses. If there is no external bus activity, A0–A15 remain at their previous values to reduce power consumption. A0–A15 are tri-stated when the bus grant signal is asserted. DATA BUS Table 1-6 Data Bus Signals Signal Names D0–D23 MOTOROLA Signal Type Input/ Output State during Reset Signal Description Tri-stated Data Bus—These signals provide the bidirectional data bus for external program and data memory accesses. D0–D23 are tristated when the BG or RESET signal is asserted. DSP56002/D, Rev. 3 1-7 Signal/Pin Descriptions Bus Control BUS CONTROL Table 1-7 Bus Control Signals State during Reset Signal Name Signal Type PS Output Tri-stated Program Memory Select—PS is asserted low for external program memory access. PS is tri-stated when the BG or RESET signal is asserted. DS Output Tri-stated Data Memory Select—DS is asserted low for external data memory access. DS is tri-stated when the BG or RESET signal is asserted. X/Y Output Tri-stated X/Y External Memory Select—This output is driven low during external Y data memory accesses. It is also driven low during external exception vector fetches when operating in the Development mode. X/Y is tri-stated when the BG or RESET signal is asserted. BS Output Pulled high Bus Select—BS is asserted when the DSP accesses the external bus, and it acts as an early indication of imminent external bus access by the DSP56002. It may also be used with the bus wait input WT to generate wait states. BS is pulled high when the BG or RESET signal is asserted. BR Input Input Signal Description Bus Request—When the Bus Request input (BR) is asserted, it allows an external device, such as another processor or DMA controller, to become the master of the external address and data buses. While the bus is released, the DSP may continue internal operations using internal memory spaces. When BR is deasserted, the DSP56002 is the bus master.When BR is asserted, the DSP56002 will release Port A, including A0–A15, D0–D23, and the bus control signals (PS, DS, X/Y, RD, WR, and BS) by placing them in the high-impedance state after execution of the current instruction has been completed. Note: BG 1-8 Output Pulled high To prevent erroneous operation, pull up the BR signal when it is not in use. Bus Grant—When this output is asserted, it grants an external device’s request for access to the external bus. This output is deasserted during hardware reset. DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Bus Control Table 1-7 Bus Control Signals (Continued) State during Reset Signal Name Signal Type BN Output Pulled low Signal Description Bus Not Required—The BN signal is asserted whenever the chip requires mastership of the external bus. During instruction cycles where the external bus is not required, BN is deasserted. If the BN signal is asserted when the DSP is not the bus master, processing has stopped and the chip is waiting to acquire bus ownership. An external arbiter may use this signal to help determine when to return bus ownership to the DSP. Note: WT Input Input The BN signal cannot be used as an early indication of imminent external bus access because it is valid later than the other bus control signals BS and WT. Bus Wait—An external device may insert wait states by asserting WT during external bus cycles. Note: To prevent erroneous operation, pull up the WT signal when it is not in use. WR Output Tri-stated Write Enable—WR is asserted low during external memory write cycles. WR is tri-stated when the BG or RESET signal is asserted. RD Output Tri-stated Read Enable—RD is asserted low during external memory read cycles. RD is tri-stated when the BG or RESET signal is asserted. MOTOROLA DSP56002/D, Rev. 3 1-9 Signal/Pin Descriptions Interrupt and Mode Control INTERRUPT AND MODE CONTROL Table 1-8 Interrupt and Mode Control Signals Signal Name Signal Type MODA/IRQA Input State during Reset Input Signal Description Mode Select A/External Interrupt Request A—This input has two functions: 1. to select the initial chip operating mode, and 2. after synchronization, to allow an external device to request a DSP interrupt. MODA is read and internally latched in the DSP when the processor exits the Reset state. MODA, MODB, and MODC select the initial chip operating mode. Several clock cycles (depending on PLL stabilization time) after leaving the Reset state, the MODA signal changes to external interrupt request IRQA. The chip operating mode can be changed by software after reset. The IRQA input is a synchronized external interrupt request that indicates that an external device is requesting service. It may be programmed to be level-sensitive or negative-edge-sensitive. If level-sensitive triggering is selected, an external pull up resistor is required for wired-OR operation. If the processor is in the Stop state and IRQA is asserted, the processor will exit the Stop state. MODB/IRQB Input Input Mode Select B/External Interrupt Request B—This input has two functions: 1. to select the initial chip operating mode, and 2. after internal synchronization, to allow an external device to request a DSP interrupt. MODB is read and internally latched in the DSP when the processor exits the Reset state. MODA, MODB, and MODC select the initial chip operating mode. Several clock cycles (depending on PLL stabilization time) after leaving the Reset state, the MODB signal changes to external interrupt request IRQB. After reset, the chip operating mode can be changed by software. The IRQB input is an external interrupt request that indicates that an external device is requesting service. It may be programmed to be level-sensitive or negative-edgetriggered. If level-sensitive triggering is selected, an external pull up resistor is required for wired-OR operation. 1-10 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Interrupt and Mode Control Table 1-8 Interrupt and Mode Control Signals (Continued) Signal Name MODC/NMI Signal Type Input State during Reset Input Signal Description Mode Select C/Non-maskable Interrupt Request—This input has two functions: 1. to select the initial chip operating mode, and 2. after internal synchronization, to allow an external device to request a non-maskable DSP interrupt. MODC is read and internally latched in the DSP when the processor exits the Reset state. MODA, MODB, and MODC select the initial chip operating mode. Several clock cycles (depending on PLL stabilization time) after leaving the Reset state, the MODC signal changes to the nonmaskable external interrupt request NMI. After reset, the chip operating mode can be changed by software. The NMI input is an external interrupt request that indicates that an external device is requesting service. It may be programmed to be level-sensitive or negative-edge-triggered. If level-sensitive triggering is selected, an external pull up resistor is required for wired-OR operation. RESET MOTOROLA Input Input Reset—This input is a direct hardware reset on the processor. When RESET is asserted low, the DSP is initialized and placed in the Reset state. A Schmitt trigger input is used for noise immunity. When the RESET signal is deasserted, the initial chip operating mode is latched from the MODA, MODB, and MODC signals. The internal reset signal is deasserted synchronous with the internal clocks. In addition, the PINIT pin is sampled and written into the PEN bit of the PLL Control Register and the CKP pin is sampled to determine the polarity of the CKOUT signal. DSP56002/D, Rev. 3 1-11 Signal/Pin Descriptions Host Interface (HI) Port HOST INTERFACE (HI) PORT Table 1-9 HI Signals Signal Name H0–H7 Signal Type State during Reset Signal Description Input Tri-stated Host Data Bus (H0–H7)—This data bus transfers data between or the host processor and the DSP56002. Output When configured as a Host Interface port, the H0–H7signals are tri-stated as long as HEN is deasserted. The signals are inputs unless HR/W is high and HEN is asserted, in which case H0–H7 become outputs, allowing the host processor to read the DSP56002 data. H0–H7 become outputs when HACK is asserted during HREQ assertion. Port B GPIO 0–7 (PB0–PB7)—These signals are General Purpose I/O signals (PB0–PB7) when the Host Interface is not selected. PB0–PB7 After reset, the default state for these signals is GPIO input. HA0–HA2 Input PB8–PB10 Input or Output Tri-stated Host Address 0—Host Address 2 (HA0–HA2)—These inputs provide the address selection for each Host Interface register. Port B GPIO 8–10 (PB8–PB10)—These signals are General Purpose I/O signals (PB8–PB10) when the Host Interface is not selected. After reset, the default state for these signals is GPIO input. HR/W PB11 Input Input or Output Tri-stated Host Read/Write—This input selects the direction of data transfer for each host processor access. If HR/W is high and HEN is asserted, H0–H7 are outputs and DSP data is transferred to the host processor. If HR/W is low and HEN is asserted, H0–H7 are inputs and host data is transferred to the DSP. HR/W must be stable when HEN is asserted. Port B GPIO 11 (PB11)—This signal is a General Purpose I/O signal called PB11 when the Host Interface is not being used. After reset, the default state for this signal is GPIO input. 1-12 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Host Interface (HI) Port Table 1-9 HI Signals (Continued) Signal Name Signal Type HEN Input PB12 Input or Output State during Reset Signal Description Tri-stated Host Enable—This input enables a data transfer on the host data bus. When HEN is asserted and HR/W is high, H0–H7 become outputs and the host processor may read DSP56002/L002 data. When HEN is asserted and HR/W is low, H0–H7 become inputs. Host data is latched inside the DSP on the rising edge of HEN. Normally, a chip select signal derived from host address decoding and an enable strobe are used to generate HEN. Port B GPIO 12 (PB12)—This signal is a General Purpose I/O signal called PB12 when the Host Interface is not being used. After reset, the default state for this signal is GPIO input. HREQ Open Tri-stated Host Request—This signal is used by the Host Interface to drain request service from the host processor, DMA controller, or a Output simple external controller. Note: PB13 Input or Output HREQ should always be pulled high when it is not in use. Port B GPIO 13 (PB13)—This signal is a General Purpose (not open-drain) I/O signal (PB13) when the Host Interface is not selected. After reset, the default state for this signal is GPIO input. HACK Input Tri-stated Host Acknowledge—This input has two functions. It provides a host acknowledge handshake signal for DMA transfers and it receives a host interrupt acknowledge compatible with MC68000 family processors. Note: PB14 Input or Output HACK should always be pulled high when it is not in use. Port B GPIO 14 (PB14)—This signal is a General Purpose I/O signal (PB14) when the Host Interface is not selected. After reset, the default state for this signal is GPIO input. MOTOROLA DSP56002/D, Rev. 3 1-13 Signal/Pin Descriptions Serial Communications Interface Port SERIAL COMMUNICATIONS INTERFACE PORT Table 1-10 Serial Communications Interface (SCI+) Signals Signal Name Signal Type RXD Input PC0 Input or Output State during Reset Signal Description Tri-stated Receive Data (RXD)—This input receives byte-oriented data and transfers the data to the SCI receive shift register. Input data can be sampled on either the positive edge or on the negative edge of the receive clock, depending on how the SCI control register is programmed. Port C GPIO 0 (PC0)—This signal is a GPIO signal called PC0 when the SCI RXD function is not being used. After reset, the default state is GPIO input. TXD Output Tri-stated Transmit Data (TXD)—This output transmits serial data from the SCI transmit shift register. In the default configuration, the data changes on the positive clock edge and is valid on the negative clock edge. The user can reverse this clock polarity by programming the SCI control register appropriately. PC1 Input or Output Port C GPIO 1 (PC1)—This signal is a GPIO signal called PC1 when the SCI TXD function is not being used. After reset, the default state is GPIO input. SCLK PC2 Input Tri-stated SCI Clock (SCLK)—This signal provides an input or output or clock from which the receive or transmit baud rate is derived in Output the Asynchronous mode, and from which data is transferred in the Synchronous mode. The direction and function of the signal is defined by the RCM bit in the SCI+ Clock Control Register (SCCR). Port C GPIO 2 (PC2)—This signal is a GPIO signal called PC2 when the SCI SCLK function is not being used. After reset, the default state is GPIO input. 1-14 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Synchronous Serial Interface Port SYNCHRONOUS SERIAL INTERFACE PORT Table 1-11 Synchronous Serial Interface (SSI) Signals Signal Name SC0 Signal Type State during Reset Input Trior stated Output Signal Description Serial Clock 0 (SC0)—This signal’s function is determined by whether the SCLK is in Synchronous or Asynchronous mode. • • PC3 In Synchronous mode, this signal is used as a serial I/O flag. In Asynchronous mode, this signal receives clock I/O. Port C GPIO 3 (PC3)—This signal is a GPIO signal called PC3 when the SSI SC0 function is not being used. After reset, the default state is GPIO input. SC1 Input Trior stated Output Serial Clock 1 (SC1)—The SSI uses this bidirectional signal to control flag or frame synchronization. This signal’s function is determined by whether the SCLK is in Synchronous or Asynchronous mode. • • In Asynchronous mode, this signal is frame sync I/O. For Synchronous mode with continuous clock, this signal is a serial I/O flag and operates like the SC0. SC0 and SC1 are independent serial I/O flags but may be used together for multiple serial device selection. Port C GPIO 4 (PC4)—This signal is a GPIO signal called PC4 when the SSI SC1 function is not being used. PC4 After reset, the default state is GPIO input. SC2 PC5 Input Trior stated Output Serial Clock 2 (SC2)—The SSI uses this bidirectional signal to control frame synchronization only. As with SC0 and SC1, its function is defined by the SSI operating mode. Port C GPIO 5 (PC5)—This signal is a GPIO signal called PC5 when the SSI SC1 function is not being used. After reset, the default state is GPIO input. MOTOROLA DSP56002/D, Rev. 3 1-15 Signal/Pin Descriptions Synchronous Serial Interface Port Table 1-11 Synchronous Serial Interface (SSI) Signals (Continued) Signal Name SCK Signal Type State during Reset Input Trior stated Output Signal Description SSI Serial Receive Clock—This bidirectional signal provides the serial bit rate clock for the SSI when only one clock is being used. Port C GPIO 6 (PC6)—This signal is a GPIO signal called PC6 when the SSI function is not being used. PC6 After reset, the default state is GPIO input. SRD Input PC7 Input or Output Tristated SSI Receive Data—This input signal receives serial data and transfers the data to the SSI Receive Shift Register. Port C GPIO 7 (PC7)—This signal is a GPIO signal called PC7 when the SSI SRD function is not being used. After reset, the default state is GPIO input. STD Output Tristated SSI Transmit Data (STD)—This output signal transmits serial data from the SSI Transmitter Shift Register. PC8 Input or Output Port C GPIO 8 (PC8)—This signal is a GPIO signal called PC8 when the SSI STD function is not being used. After reset, the default state is GPIO input. 1-16 DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions Timers TIMERS Table 1-12 Timer Signals Signal Name TIO Signal Type State during Reset Input Trior stated Output Signal Description Timer Input/Output—The TIO signal provides an interface to the timer/event counter module. When the module functions as an external event counter or is used to measure external pulse width/ signal period, the TIO is an input. When the module functions as a timer, the TIO is an output, and the signal on the TIO signal is the timer pulse. When not used by the timer module, the TIO can be programmed through the Timer Control/Status Register (TCSR) to be a General Purpose I/O signal. TIO is effectively disconnected upon leaving reset. MOTOROLA DSP56002/D, Rev. 3 1-17 Signal/Pin Descriptions On-Chip Emulation Port On-CHIP EMULATION PORT Table 1-13 On-Chip Emulation (OnCE) Signals Signal Name DSI/OS0 Signal Type Input or Output State during Reset Signal Description Low Debug Serial Input/Chip Status 0—Serial data or commands Output are provided to the OnCE controller through the DSI/OS0 signal when it is an input. The data received on the DSI signal will be recognized only when the DSP has entered the Debug mode of operation. Data is latched on the falling edge of the DSCK serial clock. Data is always shifted into the OnCE serial port Most Significant Bit (MSB) first. When the DSI/OS0 signal is an output, it works in conjunction with the OS1 signal to provide chip status information. The DSI/OS0 signal is an output when the processor is not in Debug mode. When switching from output to input, the signal is tri-stated. Note: DSCK/OS1 Input or Output Connect an external pull-down resistor to this signal. Low Debug Serial Clock/Chip Status 1—The DSCK/OS1 signal Output supplies the serial clock to the OnCE when it is an input. The serial clock provides pulses required to shift data into and out of the OnCE serial port. (Data is clocked into the OnCE on the falling edge and is clocked out of the OnCE serial port on the rising edge.) The debug serial clock frequency must be no greater than 1/8 of the processor clock frequency. When switching from input to output, the signal is tri-stated. When it is an output, this signal works with the OS0 signal to provide information about the chip status. The DSCK/OS1 signal is an output when the chip is not in Debug mode. Note: 1-18 Connect an external pull-down resistor to this signal. DSP56002/D, Rev. 3 MOTOROLA Signal/Pin Descriptions On-Chip Emulation Port Table 1-13 On-Chip Emulation (OnCE) Signals (Continued) Signal Name Signal Type DSO Output State during Reset Pulled high Signal Description Debug Serial Output—Data contained in one of the OnCE controller registers is provided through the DSO output signal, as specified by the last command received from the external command controller. Data is always shifted out the OnCE serial port Most Significant Bit (MSB) first. Data is clocked out of the OnCE serial port on the rising edge of DSCK. The DSO signal also provides acknowledge pulses to the external command controller. When the chip enters the Debug mode, the DSO signal will be pulsed low to indicate (acknowledge) that the OnCE is waiting for commands. After the OnCE receives a read command, the DSO signal will be pulsed low to indicate that the requested data is available and the OnCE serial port is ready to receive clocks in order to deliver the data. After the OnCE receives a write command, the DSO signal will be pulsed low to indicate that the OnCE serial port is ready to receive the data to be written; after the data is written, another acknowledge pulse will be provided. Note: DR Input Input Debug Request—The debug request input (DR) allows the user to enter the Debug mode of operation from the external command controller. When DR is asserted, it causes the DSP to finish the current instruction being executed, save the instruction pipeline information, enter the Debug mode, and wait for commands to be entered from the DSI line. While in Debug mode, the DR signal lets the user reset the OnCE controller by asserting it and deasserting it after receiving acknowledge. It may be necessary to reset the OnCE controller in cases where synchronization between the OnCE controller and external circuitry is lost. DR must be deasserted after the OnCE responds with an acknowledge on the DSO signal and before sending the first OnCE command. Asserting DR will cause the chip to exit the Stop or Wait state. Having DR asserted during the deassertion of RESET will cause the DSP to enter Debug mode. Note: MOTOROLA Connect an external pull-up resistor to this signal. Connect an external pull-up resistor to this signal. DSP56002/D, Rev. 3 1-19 Signal/Pin Descriptions On-Chip Emulation Port 1-20 DSP56002/D, Rev. 3 MOTOROLA SECTION 2 SPECIFICATIONS GENERAL CHARACTERISTICS The DSP56002 is fabricated in high-density HCMOS with TTL compatible inputs and outputs. MAXIMUM RATINGS CAUTION This device contains circuitry protecting against damage due to high static voltage or electrical fields; however, normal precautions should be taken to avoid exceeding maximum voltage ratings. Reliability is enhanced if unused inputs are tied to an appropriate logic voltage level (e.g., either GND or VCC). Note: In the calculation of timing requirements, adding a maximum value of one specification to a minimum value of another specification does not yield a reasonable sum. A maximum specification is calculated using a worst case variation of process parameter values in one direction. The minimum specification is calculated using the worst case for the same parameters in the opposite direction. Therefore, a “maximum” value for a specification will never occur in the same device that has a “minimum” value for another specification; adding a maximum to a minimum represents a condition that can never exist. MOTOROLA DSP56002/D, Rev. 3 2-1 Specifications Thermal characteristics Table 2-1 Absolute Maximum Ratings (GND = 0 V) Rating Symbol Value Unit Supply Voltage VCC –0.3 to +7.0 V All Input Voltages VIN (GND – 0.5) to (VCC + 0.5) V Current Drain per Pin excluding VCC and GND I 10 mA Operating Temperature Range TJ –40 to +105 °C Tstg –55 to +150 °C Storage Temperature THERMAL CHARACTERISTICS Table 2-2 Thermal Characteristics Symbol PQFP Value3 TQFP Value3 TQFP Value4 PGA Value3 Unit Junction-to-ambient thermal resistance1 RθJA or θJA 50 48 40.6 22 ˚C/W Junction-to-case thermal resistance2 RθJC or θJC 12.4 10.8 — 6.5 ˚C/W ΨJT 4.0 0.16 — N/A ˚C/W Characteristic Thermal characterization parameter Notes: 1. 2. 3. 4. 2-2 Junction-to-ambient thermal resistance is based on measurements on a horizontal-single-sided Printed Circuit Board per SEMI G38-87 in natural convection.(SEMI is Semiconductor Equipment and Materials International, 805 East Middlefield Rd., Mountain View, CA 94043, (415) 964-5111) Measurements were made with the parts installed on thermal test boards meeting the specification EIA/JEDECSI-3. Junction-to-case thermal resistance is based on measurements using a cold plate per SEMI G30-88, with the exception that the cold plate temperature is used for the case temperature. These are measured values. See note 1 for test board conditions. These are measured values; testing is not complete. Values were measured on a non-standard fourlayer thermal test board (two internal planes) at one watt in a horizontal configuration. DSP56002/D, Rev. 3 MOTOROLA Specifications DC Electrical Characteristics DC ELECTRICAL CHARACTERISTICS Table 2-3 DC Electrical Characteristics Characteristics Supply Voltage Input High Voltage •EXTAL •RESET • MODA, MODB, MODC • All other inputs Input Low Voltage • EXTAL • MODA, MODB, MODC • All other inputs Input Leakage Current EXTAL, RESET, MODA/IRQA, MODB/IRQB, MODC/NMI, DR, BR, WT, CKP, PINIT, MCBG, MCBCLR, MCCLK, D20IN Tri-state (Off–state) Input Current (@ 2.4 V/0.4 V) Output High Voltage (IOH = –0.4 mA) Output Low Voltage (IOL = 3.0 mA) HREQ IOL = 6.7 mA, TXD IOL = 6.7 mA Internal Supply Current at 40 MHz1 • In Wait mode2 • In Stop mode2 Internal Supply Current at 66 MHz1 • In Wait mode2 • In Stop mode2 Internal Supply Current at 80 MHz1 • In Wait mode2 • In Stop mode2 PLL Supply Current3 • 40 MHz • 66 MHz • 80 MHz CKOUT Supply Current4 • 40 MHz • 66 MHz • 80 MHz Input Capacitance5 Notes: 1. 2. 3. 4. 5. Symbol Min Typ Max Units VCC 4.5 5.0 5.5 V VIHC VIHR VIHM VIH 4.0 2.5 3.5 2.0 — — — — VCC VCC VCC VCC V V V V VILC VILM VIL IIN –0.5 –0.5 –0.5 –1 — — — — 0.6 2.0 0.8 1 V V V µA ITSI VOH VOL –10 2.4 — — — — 10 — 0.4 µA V V ICCI ICCW ICCS ICCI ICCW ICCS ICCI ICCW ICCS — — — — — — — — — 90 12 2 95 15 2 115 18 2 105 20 95 130 25 95 160 30 95 mA mA µA mA mA µA mA mA µA — — — 1.0 1.1 1.2 1.5 1.5 1.8 mA mA mA — — — — 14 28 34 10 20 35 42 — mA mA mA pF CIN Section 4 Design Considerations describes how to calculate the external supply current. In order to obtain these results all inputs must be terminated (i.e., not allowed to float). Values are given for PLL enabled. Values are given for CKOUT enabled. Periodically sampled and not 100% tested MOTOROLA DSP56002/D, Rev. 3 2-3 Specifications AC Electrical Characteristics AC ELECTRICAL CHARACTERISTICS The timing waveforms in the AC Electrical Characteristics are tested with a VIL maximum of 0.5 V and a VIH minimum of 2.4 V for all pins, except EXTAL, RESET, MODA, MODB, and MODC. These pins are tested using the input levels set forth in the DC Electrical Characteristics. AC timing specifications that are referenced to a device input signal are measured in production with respect to the 50% point of the respective input signal’s transition. DSP56002 output levels are measured with the production test machine VOL and VOH reference levels set at 0.8 V and 2.0 V, respectively. Pulse Width Low VIH Input Signal 90% 50% 10% Midpoint1 VIL Fall Time Note: High Rise Time The midpoint is VIL + (VIH – VIL)/2. AA0179 Figure 2-1 Signal Measurement Reference 2-4 DSP56002/D, Rev. 3 MOTOROLA Specifications Internal Clocks INTERNAL CLOCKS For each occurrence of TH, TL, TC or ICYC, substitute with the numbers in Table 2-4. DF and MF are PLL division and multiplication factors set in registers. Table 2-4 Internal Clocks Characteristics Symbol Internal Operation Frequency f Internal Clock High Period • With PLL disabled • With PLL enabled and MF ≤ 4 TH • With PLL enabled and MF > 4 Internal Clock Low Period • With PLL disabled • With PLL enabled and MF ≤ 4 TL • With PLL enabled and MF > 4 Internal Clock Cycle Time Instruction Cycle Time MOTOROLA DSP56002/D, Rev. 3 Expression ETH (Min) 0.48 × TC (Max) 0.52 × TC (Min) 0.467 × TC (Max) 0.533 × TC ETL (Min) 0.48 × TC (Max) 0.52 × TC (Min) 0.467 × TC (Max) 0.533 × TC TC ETC × DF/MF ICYC 2 × TC 2-5 Specifications External Clock (EXTAL Pin) EXTERNAL CLOCK (EXTAL PIN) The DSP56002 system clock may be derived from the on-chip crystal oscillator as shown in Figure 2-2, or it may be externally supplied. An externally supplied square wave voltage source should be connected to EXTAL, leaving XTAL physically unconnected to the board or socket. The rise and fall times of this external clock should be 4 ns maximum. EXTAL XTAL EXTAL R XTAL R1 R2 C1 XTAL1 C C C2 Fundamental Frequency Crystal Oscillator 1. The suggested crystal source is ICM, # 433163 - 4.00 (4 MHz fundamental, 20 pf load) or # 436163 - 30.00 (30 MHz fundamental, 20 pf load). 2. To reduce system cost, a ceramic resonator may be used instead of the crystal. Suggested source: Murata-Erie #CST4.00MGW040 (4 MHz with built-in load capacitors) C3 3rd Overtone Crystal Oscillator Suggested Component Values R = 680 kΩ ± 10% C = 20 pf ± 20% Note: XTAL1* L1 Suggested Component Values R1 = 470 kΩ ± 10% R2 = 330 Ω ± 10% C1 = 0.1 µf ± 20% C2 = 26 pf ± 20% C3 = 20 pf ± 10% L1 = 2.37 µH ± 10% XTAL = 40 MHz, AT cut, 20 pf load, 50 Ω max series resistance Note: 1. *3rd overtone crystal. 2. The suggested crystal source is ICM, # 471163 - 40.00 (40 MHz 3rd overtone, 20 pf load). 3. R2 limits crystal current. 4. Reference Benjamin Parzen, The Design of Crystal and Other Harmonic Oscillators, John Wiley & Sons, 1983. AA0211 Figure 2-2 Crystal Oscillator Circuits 2-6 DSP56002/D, Rev. 3 MOTOROLA Specifications External Clock (EXTAL Pin) VIHC Midpoint VILC EXTAL ETH ETL 1 2 3 ETC 4 NOTE: The midpoint is VILC + 0.5 (VIHC – VILC). AA0360 Figure 2-3 External Clock Timing Table 2-5 Clock Operation 40 MHz Num Characteristics Frequency of Operation (EXTAL Pin) 1 2 3 4 Note: Clock Input High • With PLL disabled (46.7% – 53.3% duty cycle) • With PLL enabled (42.5% – 57.5% duty cycle) 66 MHz 80 MHz Symbol Ef ETH Unit Min Max Min Max Min Max 0 40 0 66 0 80 11.7 ∞ 7.09 ∞ 5.8 ∞ 5.3 235.5 µs 5.8 ∞ 5.3 235.5 µs 10.5 235.5 µs 6.36 235.5 µs MHz ns Clock Input Low • With PLL disabled (46.7% – 53.3% duty cycle) • With PLL enabled (42.5% – 57.5% duty cycle) ETL Clock Cycle Time • With PLL disabled • With PLL enabled ETC 25 25 ∞ 15.15 ∞ 12.5 ∞ 409.6 µs 15.15 409.6 µs 12.5 409.6 µs ns ICYC 50 50 ∞ 30.3 ∞ 819.2 µs 30.3 819.2 µs ns Instruction Cycle Time = ICYC = 2TC • With PLL disabled • With PLL enabled 11.7 ∞ 7.09 ∞ 10.5 235.5 µs 6.36 235.5 µs 25 25 ∞ 819.2 µs ns External Clock Input High and External Clock Input Low are measured at 50% of the input transition. MOTOROLA DSP56002/D, Rev. 3 2-7 Specifications Phase Lock Loop (PLL) Characteristics PHASE LOCK LOOP (PLL) CHARACTERISTICS Table 2-6 Phase Lock Loop (PLL) Characteristics Characteristics VCO frequency when PLL enabled1,2,3 PLL external capacitor4 (PCAP pin to VCCP) Notes: 1. 2. 3. 4. Expression Min Max Unit MF × Ef 10 f MHz MF × Cpcap @ MF ≤ 4 @ MF > 4 MF × 340 MF × 380 MF × 480 MF × 970 pF pF The E in ETH, ETL, and ETC means external. MF is the PCTL Multiplication Factor bits (MF0–MF11). The maximum VCO frequency is limited to the internal operation frequency. Cpcap is the value of the PLL capacitor (connected between PCAP pin and VCCP) for MF = 1. The recommended value for Cpcap is: 400 pF for MF ≤ 4 and 540 pF for MF > 4. RESET, STOP, MODE SELECT, AND INTERRUPT TIMING CL = 50 pF + 2 TTL loads WS = number of Wait States (0–15) programmed into the external bus access using BCR 1 Wait State = TC Table 2-7 Reset, Stop, Mode Select, and Interrupt Timing (All Frequencies) Num 9 10 11 12 13 Characteristics Min Max Unit — 26 ns 75000TC 25TC 2500TC — — — ns ns ns Delay from Asynchronous RESET Deassertion to First External Address Output (Internal Reset Deassertion) 8TC 9TC + 20 ns Synchronous Reset Setup Time from RESET Deassertion to first CKOUT transition 8.5 TC ns Synchronous Reset Delay Time from the first CKOUT transition to the First External Address Output 8TC 8TC + 6 ns Delay from RESET Assertion to Address High Impedance (periodically sampled and not 100% tested). Minimum Stabilization Duration • Internal Oscillator PLL Disabled1 • External clock PLL Disabled2 • External clock PLL Enabled2 14 Mode Select Setup Time 21 — ns 15 Mode Select Hold Time 0 — ns 16 Minimum Edge-Triggered Interrupt Request Assertion Width 13 — ns 2-8 DSP56002/D, Rev. 3 MOTOROLA Specifications RESET, Stop, Mode Select, and Interrupt Timing Table 2-7 Reset, Stop, Mode Select, and Interrupt Timing (All Frequencies) (Continued) Num Characteristics Min Max Unit 13 — ns Delay from IRQA, IRQB, NMI Assertion to External Memory Access Address Out Valid • Caused by First Interrupt Instruction Fetch • Caused by First Interrupt Instruction Execution 5TC + TH 9TC + TH — — ns ns Delay from IRQA, IRQB, NMI Assertion to General Purpose Transfer Output Valid caused by First Interrupt Instruction Execution 11TC + TH — ns — 2 TC + TL + (TC × WS) – 23 ns — 2TC + (TC × WS) – 21 ns 16a Minimum Edge-Triggered Interrupt Request Deassertion Width 17 18 19 Delay from Address Output Valid caused by First Interrupt Instruction Execute to Interrupt Request Deassertion for Level Sensitive Fast Interrupts3 20 Delay from RD Assertion to Interrupt Request Deassertion for Level Sensitive Fast Interrupts3 21 Delay from WR Assertion to Interrupt Request Deassertion for Level Sensitive Fast Interrupts3 • WS = 0 • WS > 0 — — 2TC – 21 TC + TL + (TC × WS) – 21 ns ns Delay from General-Purpose Output Valid to Interrupt Request Deassertion for Level Sensitive Fast Interrupts3 —If Second Interrupt Instruction is: • Single Cycle • Two Cycles — — TL – 31 2TC + TL – 31 ns ns Synchronous Interrupt Setup Time from IRQA, IRQB, NMI Assertion to the second CKOUT transition 10 TC ns Synchronous Interrupt Delay Time from the second CKOUT transition to the First External Address Output Valid caused by the First Instruction Fetch after coming out of Wait State 13TC + TH 13TC + TH + 6 ns 22 23 24 25 Duration for IRQA Assertion to Recover from Stop State 12 — ns 26 Delay from IRQA Assertion to Fetch of First Interrupt Instruction (when exiting ‘Stop’)1 • Internal Crystal Oscillator Clock, OMR bit 6 = 0 • Stable External Clock, OMR Bit 6 = 1 • Stable External Clock, PCTL Bit 17 = 1 65548TC 20TC 13TC — — — ns ns ns Duration of Level Sensitive IRQA Assertion to ensure interrupt service (when exiting ‘Stop’)1 • Internal Crystal Oscillator Clock, OMR bit 6 = 0 • Stable External Clock, OMR Bit 6 = 1 • Stable External Clock, PCTL Bit 17 = 1 65534TC + TL 6TC + TL 12 — — — ns ns ns 27 MOTOROLA DSP56002/D, Rev. 3 2-9 Specifications RESET, Stop, Mode Select, and Interrupt Timing Table 2-7 Reset, Stop, Mode Select, and Interrupt Timing (All Frequencies) (Continued) Num 28 Characteristics Delay from Level Sensitive IRQA Assertion to Fetch of First Interrupt Instruction (when exiting ‘Stop’) 1 • Internal Crystal Oscillator Clock, OMR bit 6 = 0 • Stable External Clock, OMR bit 6 = 1 • Stable External Clock, PCTL bit 17= 1 Notes: 1. 2. 3. Min Max Unit 65548TC 20TC 13TC — — — ns ns ns A clock stabilization delay is required when using the on-chip crystal oscillator in two cases: • after power-on reset, and • when recovering from Stop mode. During this stabilization period, TC, TH, and TL will not be constant. Since this stabilization period varies, a delay of 75,000 × TC is typically allowed to assure that the oscillator is stable before executing programs. Circuit stabilization delay is required during reset when using an external clock in two cases: • after power-on reset, and • when recovering from Stop mode. When using fast interrupts and IRQA and IRQB are defined as level-sensitive, then timings 19 through 22 apply to prevent multiple interrupt service. To avoid these timing restrictions, the deasserted Edgetriggered mode is recommended when using fast interrupt. Long interrupts are recommended when using Level-sensitive mode. VIHR RESET 10 11 9 A0–A15 First Fetch AA0356 Figure 2-4 Reset Timing CKOUT 12 RESET 13 A0-A15, DS, PS X/Y AA0357 Figure 2-5 Synchronous Reset Timing 2-10 DSP56002/D, Rev. 3 MOTOROLA Specifications RESET, Stop, Mode Select, and Interrupt Timing VIHR RESET 14 15 VIHM MODA, MODB MODC VILM VIH VIL IRQA, IRQB, NMI AA0358 Figure 2-6 Operating Mode Select Timing First Interrupt Instruction Execution/Fetch A0–A15 RD 20 WR 21 IRQA IRQB NMI 17 19 a) First Interrupt Instruction Execution General Purpose I/O 18 22 IRQA IRQB NMI b) General Purpose I/O AA0359 Figure 2-7 External Level-Sensitive Fast Interrupt Timing MOTOROLA DSP56002/D, Rev. 3 2-11 Specifications RESET, Stop, Mode Select, and Interrupt Timing IRQA, IRQB NMI 16 IRQA, IRQB NMI 16A AA0361 Figure 2-8 External Interrupt Timing (Negative Edge-Triggered) T0, T2 CKOUT T1, T3 23 IRQA, IRQB NMI 24 A0–A15, DS, PS X/Y AA0362 Figure 2-9 Synchronous Interrupt from Wait State Timing 25 IRQA 26 A0–A15, DS, PS X/Y First Instruction Fetch AA0363 Figure 2-10 Recovery from Stop State Using IRQA 27 IRQA 28 A0–A15, DS, PS X/Y First IRQA Interrupt Instruction Fetch AA0364 Figure 2-11 Recovery from Stop State Using IRQA Interrupt Service 2-12 DSP56002/D, Rev. 3 MOTOROLA Specifications Host I/O (HI) Timing HOST I/O (HI) TIMING CL = 50 pF + 2 TTL loads Note: Active low lines should be “pulled up” in a manner consistent with the ac and dc specifications. Table 2-8 Host I/O Timing (All Frequencies) Num Min Max Unit HEN/HACK Assertion Width1 • CVR, ICR, ISR, RXL Read • IVR, RXH/M Read • Write TC + 31 26 13 — — — ns 32 HEN/HACK Deassertion Width1 • Between Two TXL Writes2 • Between Two CVR, ICR, ISR, RXL Reads3 13 2TC + 31 2TC + 31 — — — ns ns ns 33 Host Data Input Setup Time Before HEN/HACK Deassertion 4 — ns 34 Host Data Input Hold Time After HEN/HACK Deassertion 3 — ns 35 HEN/HACK Assertion to Output Data Active from High Impedance 0 — ns 36 HEN/HACK Assertion to Output Data Valid — 26 ns 37 HEN/HACK Deassertion to Output Data High Impedance5 — 18 ns 38 Output Data Hold Time After HEN/HACK Deassertion6 2.5 — ns 39 HR/W Low Setup Time Before HEN Assertion 0 — ns 40 HR/W Low Hold Time After HEN Deassertion 3 — ns 41 HR/W High Setup Time to HEN Assertion 0 — ns 42 HR/W High Hold Time After HEN/HACK Deassertion 3 — ns 43 HA0–HA2 Setup Time Before HEN Assertion 0 — ns 44 HA0–HA2 Hold Time After HEN Deassertion 3 — ns 45 DMA HACK Assertion to HREQ Deassertion4 3 45 ns 46 DMA HACK Deassertion to HREQ Assertion4,5 • For DMA RXL Read • For DMA TXL Write • All other cases TL + TC + TH TL + TC 0 — — — ns ns ns 31 Characteristics MOTOROLA DSP56002/D, Rev. 3 2-13 Specifications Host I/O (HI) Timing Table 2-8 Host I/O Timing (Continued)(All Frequencies) (Continued) Num Characteristics Min Max Unit 47 Delay from HEN Deassertion to HREQ Assertion for RXL Read4,5 TL + TC + TH — ns 48 Delay from HEN Deassertion to HREQ Assertion for TXL Write4,5 TL + TC — ns 49 Delay from HEN Assertion to HREQ Deassertion for RXL Read, TXL Write 4,5 3 58 ns Notes: 1. 2. 3. 4. 5. 6. See Host Port Considerations in Section 4. This timing must be adhered to only if two consecutive writes to the TXL are executed without polling TXDE or HREQ. This timing must be adhered to only if two consecutive reads from one of these registers are executed without polling the corresponding status bits or HREQ HREQ is pulled up by a 1 kΩ resistor. Specifications are periodically sampled and not 100% tested. May decrease to 0 ns for future versions. HREQ (Output) 31 32 HACK (Input) 41 42 HR/W (Input) 36 35 H0–H7 (Output) 37 38 Data Valid AA1084 Figure 2-12 Host Interrupt Vector Register (IVR) Read 2-14 DSP56002/D, Rev. 3 MOTOROLA Specifications Host I/O (HI) Timing HREQ (Output) 49 RXH Read HEN (Input) 47 RXM Read RXL Read 32 31 43 44 HA2–HA0 (Input) Address Valid Address Valid Address Valid 41 42 HR/W (Input) 36 37 35 38 H0–H7 (Output) Data Valid Data Valid Data Valid AA1113 Figure 2-13 Host Read Cycle (Non-DMA Mode) HREQ (Output) 49 TXH Write HEN (Input) TXM Write TXL Write 32 31 43 HA2–HA0 (Input) 48 44 Address Valid 39 Address Valid Address Valid 40 HR/W (Input) 34 33 H0–H7 (Output) Data Valid Data Valid Data Valid AA1114 Figure 2-14 Host Write Cycle (Non-DMA Mode) MOTOROLA DSP56002/D, Rev. 3 2-15 Specifications Host I/O (HI) Timing HREQ (Output) 45 46 31 32 46 RXH Read HACK (Input) RXM Read 36 46 RXL Read 37 35 38 Data Valid H0–H7 (Output) Data Valid Data Valid AA1115 Figure 2-15 Host DMA Read Cycle HREQ (Output) 45 46 31 32 46 TXH Write HACK (Input) TXM Write 33 H0–H7 (Output) 46 TXL Write 34 Data Valid Data Valid Data Valid AA1116 Figure 2-16 Host DMA Write Cycle 2-16 DSP56002/D, Rev. 3 MOTOROLA Specifications Serial Communication Interface (SCI) Timing SERIAL COMMUNICATION INTERFACE (SCI) TIMING CL = 50 pF + 2 TTL loads tSCC = Synchronous Clock Cycle Time (For internal clock, tSCC is determined by the SCI Clock Control Register and TC.) The minimum tSCC value is 8 × TC. Table 2-9 SCI Synchronous Mode Timing (All Frequencies) Num Characteristics Min Max Unit 8TC — ns 55 Synchronous Clock Cycle—tSCC 56 Clock Low Period tSCC/2 – 10.5 — ns 57 Clock High Period tSCC/2 – 10.5 — ns 58 < intentionally blank > — — — 59 Output Data Setup to Clock Falling Edge (Internal Clock) tSCC/4 + TL – 26 — ns 60 Output Data Hold After Clock Rising Edge (Internal Clock) tSCC/4 – TL – 8 — ns 61 Input Data Setup Time Before Clock Rising Edge (Internal Clock) tSCC/4 + TL + 23 — ns 62 Input Data Not Valid Before Clock Rising Edge (Internal Clock) — tSCC/4 + TL – 5.5 ns 63 Clock Falling Edge to Output Data Valid (External Clock) — 32.5 ns 64 Output Data Hold After Clock Rising Edge (External Clock) TC + 3 — ns 65 Input Data Setup Time Before Clock Rising Edge (External Clock) 16 — ns 66 Input Data Hold Time After Clock Rising Edge (External Clock) 21 — ns Table 2-10 SCI Asynchronous Mode Timing—1X Clock Num Characteristics Min Max Unit 64TC — ns 67 Asynchronous Clock Cycle—tACC 68 Clock Low Period tACC/2 – 11 — ns 69 Clock High Period tACC/2 – 11 — ns 70 < intentionally blank > — — — 71 Output Data Setup to Clock Rising Edge (Internal Clock) tACC/2 – 51 — ns 72 Output Data Hold After Clock Rising Edge (Internal Clock) tACC/2 – 51 — ns MOTOROLA DSP56002/D, Rev. 3 2-17 Specifications Serial Communication Interface (SCI) Timing 55 57 56 RCLK TCLK (Output) 59 60 TXD Data Valid 61 62 Data Valid RXD a) Internal Clock 55 57 56 RCLK TCLK (Input) 63 64 TXD Data Valid 65 66 RXD Data Valid b) External Clock AA0388 Figure 2-17 SCI Synchronous Mode Timing 67 69 68 1X TCLK (Output) 72 71 TXD Note: Data Valid In the wire-OR mode, TXD can be pulled up by 1 kΩ. AA0389 Figure 2-18 SCI Asynchronous Mode Timing 2-18 DSP56002/D, Rev. 3 MOTOROLA Specifications Synchronous Serial Interface (SSI) Timing SYNCHRONOUS SERIAL INTERFACE (SSI) TIMING CL = 50 pF + 2 TTL loads tSSICC = SSI clock cycle time TXC (SCK Pin) = Transmit Clock RXC (SC0 or SCK Pin) = Receive Clock FST (SC2 Pin) = Transmit Frame Sync FSR (SC1 or SC2 Pin) = Receive Frame Sync i ck = Internal Clock x ck = External Clock g ck = Gated Clock i ck a = Internal Clock, Asynchronous Mode (Asynchronous implies that STD and SRD are two different clocks) i ck s = Internal Clock, Synchronous Mode (Synchronous implies that STD and SRD are the same clock) bl = bit length wl = word length Table 2-11 SSI Timing 40 MHZ or 66 MHz Num 80 MHz Characteristics Min Max Min Max Case Unit 80 Clock Cycle–tSSICC1 4TC 3TC — — 4TC 3TC — — i ck x ck ns 81 Clock High Period tSSICC/2 – 10.8 TC + TL — — TC + 5 TC + 5 — — i ck x ck ns 82 Clock Low Period tSSICC/2 – 10.8 TC + TL — — TC + 5 TC + 5 — — i ck x ck ns 84 RXC Rising Edge to FSR Out (bl) High — — 40.8 25.8 — — 30 25.8 x ck i ck a ns 85 RXC Rising Edge to FSR Out (bl) Low — — 35.8 25.8 — — 30 25.8 x ck i ck a ns 86 RXC Rising Edge to FSR Out (wl) High — — 35.8 20.8 — — 30 20.8 x ck i ck a ns 87 RXC Rising Edge to FSR Out (wl) Low — — 35.8 20.8 — — 30 20.8 x ck i ck a ns 88 Data In Setup Time Before RXC (SCK in Synchronous Mode) Falling Edge 3.3 15.8 13 — — — 3.3 15.8 13 — — — x ck i ck a i ck s ns MOTOROLA DSP56002/D, Rev. 3 2-19 Specifications Synchronous Serial Interface (SSI) Timing Table 2-11 SSI Timing (Continued) 40 MHZ or 66 MHz Num 80 MHz Characteristics Min Max Min Max Case Unit 89 Data In Hold Time After RXC Falling Edge 18 3.3 — — 18 3.3 — — x ck i ck ns 90 FSR Input (bl) High Before RXC Falling Edge 0.8 17.4 — — 0.8 17.4 — — x ck i ck a ns 91 FSR Input (wl) High Before RXC Falling Edge 3.3 18.3 — — 3.3 18.3 — — x ck i ck a ns 92 FSR Input Hold Time After RXC Falling Edge 18.3 3.3 — — 18.3 3.3 — — x ck i ck ns 93 Flags Input Setup Before RXC Falling Edge 0.8 16.7 — — 0.8 16.7 — — x ck i ck s ns 94 Flags Input Hold Time After RXC Falling Edge 18.3 3.3 — — 18.3 3.3 — — x ck i ck s ns 95 TXC Rising Edge to FST Out (bl) High — — 31.6 15.8 — — 30 15.8 x ck i ck ns 96 TXC Rising Edge to FST Out (bl) Low — — 33.3 18.3 — — 30 18.3 x ck i ck ns 97 TXC Rising Edge to FST Out (wl) High — — 30.8 18.3 — — 30 18.3 x ck i ck ns 98 TXC Rising Edge to FST Out (wl) Low — — 33.3 18.3 — — 30 18.3 x ck i ck ns 99 TXC Rising Edge to Data Out Enable from High Impedance — 33.3 + TH 20.8 — 30 x ck ns — 20.8 i ck TXC Rising Edge to Data Out Valid — — 30 x ck — 33.3 + TH 22.4 — 22.4 i ck — — 35.8 20.8 — — 30 20.8 x ck i ck 100 101 2-20 TXC Rising Edge to Data Out High Impedance 2 — DSP56002/D, Rev. 3 ns ns MOTOROLA Specifications Synchronous Serial Interface (SSI) Timing Table 2-11 SSI Timing (Continued) 40 MHZ or 66 MHz Num 80 MHz Characteristics Min Max Min Max Case Unit 101A TXC Falling Edge to Data Out High Impedance 2 — TC + TH — TC + TH g ck ns 102 FST Input (bl) Setup Time Before TXC Falling Edge 0.8 18.3 0.8 18.3 — x ck i ck ns — 103 FST Input (wl) to Data Out Enable from High Impedance — 30.8 — 30.8 104 FST Input (wl) Setup Time Before TXC Falling Edge 0.8 20.0 — — 0.8 20.0 — — x ck i ck ns 105 FST Input Hold Time After TXC Falling Edge 18.3 3.3 — — 18.3 3.3 — — x ck i ck ns 106 Flag Output Valid After TXC Rising Edge — — 32.5 20.8 — — 30 20.8 x ck i ck ns Notes: 1. 2. ns For internal clock, External Clock Cycle is defined by Icyc and SSI control register. Periodically sampled and not 100% tested MOTOROLA DSP56002/D, Rev. 3 2-21 Specifications Synchronous Serial Interface (SSI) Timing 80 TXC (Input/ Output) 81 82 95 96 FST (Bit) Out 97 98 FST (Word) Out 100 101A 100 99 101 Data Out First Bit Last Bit 102 105 FST (Bit) In 103 104 105 FST (Word) In 106 See Note Flags Out Note: In the Network mode, output flag transitions can occur at the start of each time slot within the frame. In the Normal mode, the output flag state is asserted for the entire frame period. AA0390 Figure 2-19 SSI Transmitter Timing 2-22 DSP56002/D, Rev. 3 MOTOROLA Specifications Synchronous Serial Interface (SSI) Timing 80 81 82 RXC (Input/Output) 84 85 FSR (Bit) Out 86 87 FSR (Word) Out 88 Data In 89 First Bit Last Bit 90 92 FSR (Bit) In 91 92 FSR (Word) In 93 94 Flags In AA0391 Figure 2-20 SSI Receiver Timing MOTOROLA DSP56002/D, Rev. 3 2-23 Specifications External Bus Asynchronous Timing EXTERNAL BUS ASYNCHRONOUS TIMING CL = 50 pF + 2 TTL loads WS = Number of Wait States (0 to 15), as determined by BCR register Capacitance Derating: The DSP56002 External Bus Timing Specifications are designed and tested at the maximum capacitive load of 50 pF, including stray capacitance. Typically, the drive capability of the External Bus pins (A0–A15, D0–D23, PS, DS, RD, WR, X/Y, EXTP) derates linearly at 1 ns per 12 pF of additional capacitance from 50 pF to 250 pF of loading. Port B and C pins (HI, SCI, SSI, and Timer) derate linearly at 1 ns per 5 pF of additional capacitance from 50 pF to 250 pF of loading. Active low lines should be “pulled up” in a manner consistent with the AC and DC specifications. Table 2-12 External Bus Asynchronous Timing 40 MHz No. 80 MHz Unit Min 115 Delay from BR Assertion to BG Assertion • With no 2TC + external access TH from the DSP • During external TC + TH read or write access • During external TC + TH read-modifywrite access • During Stop ∞ mode— external bus will not be released and BG will not go low • During Wait TH mode 116 Delay from BR Deassertion to BG Deassertion 2-24 66 MHz Characteristics 2TC Max Min Max Min Max 4TC + TH + 14 2TC + TH 4TC + TH + 14 2TC + TH 4TC + TH + 14 ns 4TC + TH + TC + TH 4TC + TH + TC + TH 4TC + TH + (TC × WS) + 14 (TC × WS) + 14 (TC × WS) + 14 ns 6TC + TH + TC + TH 6TC + TH + TC + TH 6TC + TH + ns (2TC × WS) +14 (2TC × WS) +14 (2TC × WS) +14 14 ∞ 14 ∞ 14 ns TC + TH + 15 TH TC + TH + 15 TH TC + TH + 15 ns 4TC + 12.5 2TC 4TC + 12.5 2TC 4TC + 12.5 ns DSP56002/D, Rev. 3 MOTOROLA Specifications External Bus Asynchronous Timing Table 2-12 External Bus Asynchronous Timing (Continued) 40 MHz No. 66 MHz 80 MHz Characteristics Unit Min 117 BG Deassertion Duration • During Wait TC – 5.5 mode • All other cases 2TC + TH – 5.5 Max Min Max Min Max — TC – 5.5 — TC – 5.5 — ns — 2TC + TH – 5.5 — 2TC + TH – 5.5 — ns 118 Delay from Address, Data, and Control Bus High Impedance to BG Assertion 0 — 0 — 0 — ns 119 Delay from BG Deassertion to Address and Control Bus Enabled 0 TH 0 TH 0 TH ns TL – 6 TC – 6 — — TL – 4.5 TC – 4.5 — — TL – 4.5 TC – 4.5 — — ns ns TC – 4 WS × TC + TL — — TC – 4 WS × TC + TL — — TC – 2 WS × TC + TL — — ns ns TH – 6 — TH – 4 — TH – 4 — ns TH – 4 0 — — TH – 4 0 — — TH – 4 0 — — ns ns TH – 7 TH – 2.5 TH – 5 TH – 1.5 TH – 5 TH – 1.5 ns TL – 0.8 WS × TC + TL – 0.8 — — TL – 0.4 WS × TC + TL – 0.4 — — TL – 0.5 WS × TC + TL – 0.5 — — ns ns 120 Address Valid to WR Assertion • WS = 0 • WS > 0 121 WR Assertion Width • WS = 0 • WS > 0 122 WR Deassertion to Address Not Valid 123 WR Assertion to Data Out Active From High Impedance • WS = 0 • WS > 0 124 Data Out Hold Time from WR Deassertion (the maximum specification is periodically sampled, and not 100% tested) 125 Data Out Setup Time to WR Deassertion • WS = 0 • WS > 0 MOTOROLA DSP56002/D, Rev. 3 2-25 Specifications External Bus Asynchronous Timing Table 2-12 External Bus Asynchronous Timing (Continued) 40 MHz No. 66 MHz 80 MHz Characteristics Unit Min Max Min Max Min Max TH — TH – 1 — TH — ns TC + TL – 6 ((WS + 1) × TC) + TL – 6 — TC + TL – 6 ((WS + 1) × TC) + TL – 6 — TC + TL – 6 ((WS + 1) × TC) + TL – 6 — ns — ns 0 — 0 — 0 — ns TC – 4 ((WS + 1) × TC) – 4 — — TC – 4 ((WS + 1) × TC) – 4 — — TC – 4 ((WS + 1) × TC) – 4 — — ns ns — — TC + TL – 9.5 ((WS+1) × TC) + TL – 9.5 — — TC + TL – 7 ((WS+1) × TC) + TL – 7 — — TC + TL – 6 ((WS+1) × TC) + TL – 6 ns ns TL – 4.5 — TL – 4.5 — TL – 4.5 — ns — — TC – 7.5 ((WS+1) × TC) – 7.5 — — TC – 5.5 ((WS+1) × TC) – 5.5 — — 133 WR Deassertion to RD Assertion TC – 7 — TC – 5 — TC – 5 — ns 134 RD Deassertion to RD Assertion TC – 4 — TC – 2.5 — TC – 2.5 — ns TC – 4 TC + TH – 4 — — TC – 3 TC + TH – 3 — — TC – 3 TC + TH – 3 — — ns ns 126 RD Deassertion to Address Not Valid 127 Address Valid to RD Deassertion • WS = 0 • WS > 0 128 Input Data Hold Time to RD Deassertion 129 RD Assertion Width • WS = 0 • WS > 0 130 Address Valid to Input Data Valid • WS = 0 • WS > 0 131 Address Valid to RD Assertion 132 RD Assertion to Input Data Valid • WS = 0 • WS > 0 135 WR Deassertion to WR Assertion • WS = 0 • WS > 0 2-26 — — DSP56002/D, Rev. 3 TC – 5.5 ns ((WS+1) × TC) – ns 5.5 MOTOROLA Specifications External Bus Asynchronous Timing Table 2-12 External Bus Asynchronous Timing (Continued) 40 MHz No. 66 MHz 80 MHz Characteristics 136 RD Deassertion to WR Assertion • WS = 0 • WS > 0 Unit Min Max Min Max Min Max TC – 4 TC + TH – 4 — — TC – 2.5 TC + TH – 2.5 — — TC – 2.5 TC + TH – 2.5 — — ns ns BR 115 116 BG 117 119 118 A0–A15, PS DS, X/Y, RD, WR D0–D23 AA0392 Figure 2-21 Bus Request / Bus Grant Timing MOTOROLA DSP56002/D, Rev. 3 2-27 Specifications External Bus Asynchronous Timing A0–A15, DS, PS, X/Y (See Note) 126 127 131 129 134 RD 120 135 122 121 133 136 WR 132 123 130 125 D0–D23 Note: 128 124 Data Out Data In During Read-Modify-Write instructions, the address lines do not change state. AA0393 Figure 2-22 External Bus Asynchronous Timing 2-28 DSP56002/D, Rev. 3 MOTOROLA Specifications External Bus Synchronous Timing EXTERNAL BUS SYNCHRONOUS TIMING CL = 50 pF + 2 TTL loads Capacitance Derating: The DSP56002 external bus timing specifications are designed and tested at the maximum capacitive load of 50 pF, including stray capacitance. Typically, the drive capability of the external bus pins (A0–A15, D0–D23, PS, DS, RD, WR, X/Y) derates linearly at 1 ns per 12 pF of additional capacitance from 50 pF to 250 pF of loading. Port B and C pins (HI, SCI, SSI, and Timer) derate linearly at 1 ns per 5 pF of additional capacitance from 50 pF to 250 pF of loading. Active-low lines should be “pulled up” in a manner consistent with the ac and dc specifications. Table 2-13 External Bus Synchronous Timing 40 MHz Num 66 MHz 80 MHz Characteristics Unit Min Max Min Max Min Max First CKOUT transition to Address Valid Second CKOUT transition to WR Assertion1 • WS = 0 • WS > 0 — 6.2 — 5 — 5 — — 4.4 TH + 4.4 — — 4 TH + 4 — — 4 TH + 4 142 Second CKOUT transition to WR Deassertion 1.3 9.1 1 5 1 5 ns 143 Second CKOUT transition to RD Assertion — 3.9 — 3.9 — 3.9 ns 144 Second CKOUT transition to RD Deassertion 0 3.4 –3 3 –3 3 ns 145 First CKOUT transition to Data-Out Valid — 5.4 — 4.5 — 4.5 ns 146 First CKOUT transition to Data-Out Invalid3 0 — 0 — 0 — ns 147 Data-In Valid to second CKOUT transition (Setup) 3.4 — 3.4 — 3.4 — ns 148 Second CKOUT transition to Data-In Invalid (Hold) 0 — 0 — 0 — ns 149 First CKOUT transition to Address Invalid3 0 — 0 — 0 — ns 140 141 Notes: 1. 2. 3. 4. 5. ns ns ns AC timing specifications which are referenced to a device input signal are measured in production with respect to the 50% point of the respective input signal’s transition. WS are wait state values specified in the BCR. First CKOUT transition to data-out invalid (specification # T146) and first CKOUT transition to address invalid (specification # T149) indicate the time after which data/address are no longer guaranteed to be valid. Timings are given from CKOUT midpoint to VOL or VOH of the corresponding pin(s). First CKOUT transition is a falling edge of CKOUT for CKP = 0. MOTOROLA DSP56002/D, Rev. 3 2-29 Specifications External Bus Synchronous Timing T0 T1 T2 T3 T0 T1 T2 T3 T0 CKOUT A0–A15 DS, PS X/Y 140 143 144 149 RD 141 142 WR 147 D0–D23 Data Out 145 148 Data In 146 BN 171 172 EXTAL 170 Note: During Read-Modify-Write Instructions, the address lines do not change states. AA0395 Figure 2-23 Synchronous Bus Timing 2-30 DSP56002/D, Rev. 3 MOTOROLA Specifications External Bus Synchronous Timing Table 2-14 Bus Strobe/Wait Timing 40 MHz No. 66 MHz 80 MHz Characteristics Unit Min Max Min Max Min Max 150 First CKOUT transition to BS Assertion — 5.6 — 5.6 — 5.6 ns 151 WT Assertion to first CKOUT transition (setup time) 5.3 — 5.3 — 5.3 — ns 152 First CKOUT transition to WT Deassertion for Minimum Timing 0 TC – 7.9 0 TC – 7.9 0 TC – 6 ns 153 WT Deassertion to first CKOUT transition for Maximum Timing (2 wait states) 7.9 — 7.9 — 6 — ns 154 Second CKOUT transition to BS Deassertion — 5.2 — 5.2 — 5.2 ns 155 BS Assertion to Address Valid 0 2.4 0 2.4 0 2.4 ns 156 BS Assertion to WT Assertion1 0 TC – 10.9 0 TC – 10.9 0 TC – 8.8 ns 157 BS Assertion to WT Deassertion1,3 (WS–1) × WS × TC – TC 13.5 158 WT Deassertion to BS Deassertion TC + TL + 3.3 2× TC+TL+ 7.8 TC + TL + 3.3 2× TC+TL+ 7.8 159 Minimum BS Deassertion Width for Consecutive External Accesses TH – 1 — TH – 1 TH – 4.6 — 161 Data-In Valid to RD Deassertion (Set Up) 3.4 162 BR Assertion to second CKOUT transition for Minimum Timing 9.5 160 BS Deassertion to Address Invalid2 MOTOROLA (WS–1) × WS × TC – TC 13.5 (WS–1) × WS × TC – TC 10.9 ns TC + TL + 3.3 2× TC+TL+ 7.8 ns — TH – 1 — ns TH – 4.6 — TH – 4.6 — ns — 3.4 — 3.4 — ns TC 9.5 TC 9.5 TC ns DSP56002/D, Rev. 3 2-31 Specifications External Bus Synchronous Timing Table 2-14 Bus Strobe/Wait Timing (Continued) 40 MHz No. 66 MHz 80 MHz Characteristics Unit Min Max Min Max Min Max 163 BR Deassertion to second CKOUT transition for Minimum Timing 8 TC 8 TC 8 TC ns 164 First CKOUT transition to BG Assertion — 8.8 — 8.8 — 8.8 ns 165 First CKOUT transition to BG Deassertion — 5.3 — 5.3 — 5.3 ns 170 EXTAL to CKOUT with PLL Disabled EXTAL to CKOUT5 with PLL Enabled and MF < 5 3 9.7 3 9.7 3 9.7 ns 0.3 3.7 0.3 3.7 0.3 3.7 ns 171 Second CKOUT transition to BN Assertion — 5.7 — 5.7 — 5.7 ns 172 Second CKOUT transition to BN Deassertion — 5 — 5 — 5 ns Notes: 1. 2. 3. 4. 5. 2-32 If wait states are also inserted using the BCR and if the number of wait states is greater than 2, then specification numbers T156 and T157 can be increased accordingly. BS deassertion to address invalid indicates the time after which the address are no longer guaranteed to be valid. The minimum number of wait states when using BS/WT is two (2). For read-modify-write instructions, the address lines will not change states between the read and the write cycle. However, BS will deassert before asserting again for the write cycle. If wait states are desired for each of the read and write cycle, the WT pin must be asserted once for each cycle. When EXTAL frequency is less than 33 MHz, then timing T170 is not guaranteed for a period of 1000 × TC after PLOCK assertion following the events below: • when enabling the PLL operation by software, • when changing the Multiplication Factor, • when recovering from the Stop state if the PLL was turned off and it is supposed to turn, on • when exiting the Stop state. DSP56002/D, Rev. 3 MOTOROLA Specifications External Bus Synchronous Timing T2 Tw T2 T3 T0 T1 T2 Tw T2 T3 T0 T1 CKOUT 162 164 163 165 BR BG AA0396 Figure 2-24 Synchronous Bus Request / Bus Grant Timing MOTOROLA DSP56002/D, Rev. 3 2-33 Specifications External Bus Synchronous Timing T0 T1 T2 Tw T2 Tw T2 T3 T0 CKOUT 140 149 A0–A15, PS, DS, X/Y 150 154 BS 152 151 153 WT 143 144 RD 147 148 Data In D0–D23 141 142 WR 145 D0–D23 Note: 146 Data Out During Read-Modify-Write instructions, the address lines do not change state. However, BS will deassert before asserting again for the write cycle. AA0397 Figure 2-25 Synchronous BS / WT Timings 2-34 DSP56002/D, Rev. 3 MOTOROLA Specifications External Bus Synchronous Timing A0–A15, PS, DS, X/Y 155 160 BS 157 158 156 158 WT 131 126 RD 161 D0–D23 128 Data In 120 122 WR 123 D0–D23 Note: 125 124 Data Out During Read-Modify-Write instructions, the address lines do not change state. However, BS will deassert before asserting again for the write cycle. AA0398 Figure 2-26 Asynchronous BS / WT Timings MOTOROLA DSP56002/D, Rev. 3 2-35 Specifications OnCE Port Timing OnCE PORT TIMING CL = 50 pF + 2 TTL loads Table 2-15 OnCE Port Timing Num Characteristics Min Max Unit 230 DSCK Low 40 — ns 231 DSCK High 40 — ns 232 DSCK Cycle Time 200 — ns 233 DR Asserted to DSO (ACK) Asserted 5TC — ns 234 DSCK High to DSO Valid — 42 ns 235 DSCK High to DSO Invalid 3 — ns 236 DSI Valid to DSCK Low (Setup) 15 — ns 237 DSCK Low to DSI Invalid (Hold) 3 — ns 238 Last DSCK Low to OS0–OS1, ACK Active 3TC + TL — ns 239 DSO (ACK) Asserted to First DSCK High 2TC — ns 240 DSO (ACK) Assertion Width 4TC + TH – 3 5TC + 7 ns 241 DSO (ACK) Asserted to OS0–OS1 High Impedance2 — 0 ns 242 OS0–OS1 Valid to second CKOUT transition TC – 21 — ns 243 Second CKOUT transition to OS0–OS1 Invalid 0 — ns 244 Last DSCK Low of Read Register to First DSCK High of Next Command 7TC + 10 — ns 245 Last DSCK Low to DSO Invalid (Hold) 3 — ns 246 DR Assertion to second CKOUT transition for Wake Up from Wait state 12 TC ns 247 Second CKOUT transition to DSO after Wake Up from Wait state 17TC — ns 248 DR Assertion Width • To recover from Wait state • To recover from Wait state and enter Debug mode 15 13TC + 15 12TC – 15 — ns 17TC — ns 15 15 15 65548TC + TL 20TC + TL 13TC + TL ns ns ns 249 250A 2-36 DR Assertion to DSO (ACK) Valid (enter Debug mode) After Asynchronous Recovery from Wait State DR Assertion Width to Recover from Stop state1 • Stable External Clock, OMR Bit 6 = 0 • Stable External Clock, OMR Bit 6 = 1 • Stable External Clock, PCTL Bit 17= 1 DSP56002/D, Rev. 3 MOTOROLA Specifications OnCE Port Timing Table 2-15 OnCE Port Timing Num 250B 251 Notes: Characteristics Min Max Unit DR Assertion Width to Recover from Stop state and enter Debug mode1 • Stable External Clock,OMR Bit 6 = 0 • Stable External Clock,OMR Bit 6 = 1 • Stable External Clock,PCTL Bit 17= 1 65549TC + TL 21TC + TL 14TC + TL — — — ns ns ns DR Assertion to DSO (ACK) Valid (enter Debug mode) after recovery from Stop state1 • Stable External Clock, OMR Bit 6 = 0 • Stable External Clock, OMR Bit 6 = 1 • Stable External Clock, PCTL Bit 17= 1 65553TC + TL 25TC + TL 18TC + TL — — — ns ns ns 1. 2. A clock stabilization delay is required when using the on-chip crystal oscillator in two cases: • after power-on Reset, and • when recovering from Stop mode. During this stabilization period, TC, TH, and TL will not be constant. Since this stabilization period varies, a delay of 75,000 × TC is typically allowed to assure that the oscillator is stable before executing programs. While it is possible to set OMR bit 6 = 1 when using the internal crystal oscillator, it is not recommended and these specifications do not guarantee timings for that case. The maximum specified is periodically sampled and not 100% tested. 230 DSCK (Input) 231 232 AA0399 Figure 2-27 OnCE Serial Clock Timing DR (Input) 233 DSO (Output) (ACK) AA0400 Figure 2-28 OnCE Acknowledge Timing MOTOROLA DSP56002/D, Rev. 3 2-37 Specifications OnCE Port Timing DSCK (Input) (OS1) (Last) DSO (Output) (ACK) 236 237 238 DSI (Input) (OS0) (See Note) Note: High Impedance, external pull-down resistor AA0501 Figure 2-29 OnCE Data I/O To Status Timing DSCK (Input) (Last) 234 235 245 (See Note) DSO (Output) Note: High Impedance, external pull-down resistor AA0502 Figure 2-30 OnCE Read Timing 239 OS1 (Output) (See Note) 241 (DSCK Input) 240 DSO (Output) (DSO Output) (DSI Input) OS0 (Output) 241 (See Note) 236 237 Note: High Impedance, external pull-down resistor AA0503 Figure 2-31 OnCE Data I/O To Status Timing 2-38 DSP56002/D, Rev. 3 MOTOROLA Specifications OnCE Port Timing CKOUT 242 243 OS0–OS1 (Output) (See Note) Note: High Impedance, external pull-down resistor AA0504 Figure 2-32 OnCE CKOUT To Status Timing DSCK (Input) (Next Command) 244 AA0505 Figure 2-33 OnCE Read Register to Next Command Timing CKOUT T0, T2 T1, T3 248 DR (Input) 246 247 DSO (Output) AA0506 Figure 2-34 Synchronous Recovery from Wait State 248 DR (Input) 249 DSO (Output) AA0507 Figure 2-35 Asynchronous Recovery from Wait State MOTOROLA DSP56002/D, Rev. 3 2-39 Specifications OnCE Port Timing 250 DR (Input) 251 DSO (Output) AA0508 Figure 2-36 Asynchronous Recovery from Stop State 2-40 DSP56002/D, Rev. 3 MOTOROLA Specifications Timer Timing TIMER TIMING CL = 50 pF + 2 TTL loads Table 2-16 Timer Timing Num Characteristics Min Max Unit 2TC + 7 — ns 2TC + 7 — ns 10 TC ns 5TC + TH — ns 260 261 TIO Low TIO High 262 Synchronous Timer Setup Time from TIO (input) Assertion to CKOUT Rising Edge 263 Synchronous Timer Delay Time from CKOUT Rising Edge to the External Memory Access Address Out Valid Caused by First Interrupt Instruction Execution 264 CKOUT Rising Edge to TIO (output) Assertion 0 8 ns 265 CKOUT Rising Edge to TIO (output) Deassertion 0 8 ns 266 CKOUT Rising Edge to TIO (General Purpose Output) 0 8 ns TIO 260 261 AA0509 Figure 2-37 TIO Timer Event Input CKOUT TIO (Input) 262 ADDRESS 263 First Interrupt Instruction Execution AA0510 Figure 2-38 Timer Interrupt Generation MOTOROLA DSP56002/D, Rev. 3 2-41 Specifications Timer Timing CKOUT TIO (Output) 264 265 AA0511 Figure 2-39 External Pulse Generation fetch the instruction MOVE X0,X:(R0); X0 contains the new value of TIO ; and R0 contains the address of TCSR 266 CKOUT A0–A15 PS, DS EXTP, X/Y TIO (Output) AA0512 Figure 2-40 GPIO Output Timing 2-42 DSP56002/D, Rev. 3 MOTOROLA SECTION 3 PACKAGING PIN-OUT AND PACKAGE INFORMATION This sections provides information about the available packages for this product, including diagrams of the package pinouts and tables describing how the signals described in Section 1 are allocated for each package. The DSP56002 is available in three package types: MOTOROLA • 132-pin Plastic Quad Flat Pack (PQFP) • 144-pin Thin Quad Flat Pack (TQFP) • 132-pin Ceramic Pin Grid Array (PGA) DSP56002/D, Rev. 3 3-1 Packaging Pin-out and Package Information PQFP Package Description 18 Orientation Mark (Chamfered Edge) (Top View) 51 84 GNDD D21 D20 VCCD D19 D18 GNDD D17 D16 D15 D14 GNDD D13 D12 VCCD D11 D10 GNDD GNDQ VCCQ D9 D8 D7 D6 GNDD D5 D4 VCCD D3 D2 GNDD D1 D0 DR DSO DSI/OS0 BS X/Y GNDA DS VCCA PS A0 A1 GNDA A2 A3 A4 VCCQ GNDQ A5 VCCA GNDA A6 A7 A8 A9 GNDA A10 A11 A12 VCCA A13 GNDA A14 A15 H4/PB4 H3/PB3 VCCH H2/PB2 GNDH H1/PB1 H0/PB0 RXD/PC0 TXD/PC1 GNDS SCLK/PC2 SC0/PC3 VCCS SCK/PC6 SC2/PC5 STD/PC8 GNDS SC1/PC4 GNDQ VCCQ SRD/PC7 TIO NC BN WT BG BR VCCC WR RD GNDC NC DSCK/OS1 117 1 H5/PB5 GNDH H6/PB6 H7/PB7 HREQ/PB13 HR/W/PB11 GNDH HEN/PB12 VCCH HACK/PB14 HA0/PB8 HA1/PB9 GNDH HA2/PB10 GNDQ VCCQ EXTAL XTAL PINIT PLOCK GNDP PCAP VCCP CKP RESET VCCCK CKOUT GNDCK MODA/IRQA MODB/IRQB MODC/NMI D23 D22 Top and bottom views of the PQFP package are shown in Figure 3-1 and Figure 3-2 with their pin-outs. Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). 3. To simplify locating the pins, each fifth pin is shaded in the illustration. AA0611 Figure 3-1 Top View of the 132-pin Plastic Quad Flat Pack (PQFP) Package 3-2 DSP56002/D, Rev. 3 MOTOROLA Packaging D22 D23 MODC/NMI MODB/IRQB MODA/IRQA GNDCK CKOUT VCCCK RESET CKP VCCP PCAP GNDP PLOCK PINIT XTAL EXTAL VCCQ GNDQ HA2/PB10 GNDH HA1/PB9 HA0/PB8 HACK/PB14 VCCH HEN/PB12 GNDH HR/W/PB11 HREQ/PB13 H7/PB7 H6/PB6 GNDH H5/PB5 Pin-out and Package Information 117 1 18 Orientation Mark (Chamfered Edge on Top Side) 51 (Bottom View) 84 H4/PB4 H3/PB3 VCCH H2/PB2 GNDH H1/PB1 H0/PB0 RXD/PC0 TXD/PC1 GNDS SCLK/PC2 SC0/PC3 VCCS SCK/PC6 SC2/PC5 STD/PC8 GNDS SC1/PC4 GNDQ VCCQ SRD/PC7 TIO NC BN WT BG BR VCCC WR RD GNDC NC DSCK/OS1 A15 A14 GNDA A13 VCCA A12 A11 A10 GNDA A9 A8 A7 A6 GNDA VCCA A5 GNDQ VCCQ A4 A3 A2 GNDA A1 A0 PS VCCA DS GNDA X/Y BS DSI/OS0 DSO DR GNDD D21 D20 VCCD D19 D18 GNDD D17 D16 D15 D14 GNDD D13 D12 VCCD D11 D10 GNDD GNDQ VCCQ D9 D8 D7 D6 GNDD D5 D4 VCCD D3 D2 GNDD D1 D0 Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). 3. To simplify locating the pins, each fifth pin is shaded in the illustration. AA0612 Figure 3-2 Bottom View of the 132-pin Plastic Quad Flat Pack (PQFP) Package MOTOROLA DSP56002/D, Rev. 3 3-3 Packaging Pin-out and Package Information The DSP56002 signals that may be programmed as General Purpose I/O are listed with their primary function in Table 3-9. Table 3-1 DSP56002 General Purpose I/O Pin Identification in PQFP Package 3-4 Pin Number Primary Function Port GPIO ID 24 H0 B PB0 23 H1 PB1 21 H2 PB2 19 H3 PB3 18 H4 PB4 17 H5 PB5 15 H6 PB6 14 H7 PB7 7 HA0 PB8 6 HA1 PB9 4 HA2 PB10 12 HR/W PB11 10 HEN PB12 13 HREQ PB13 8 HACK PB14 25 RXD 26 TXD PC1 28 SCLK PC2 29 SC0 PC3 35 SC1 PC4 32 SC2 PC5 31 SCK PC6 38 SRD PC7 33 STD PC8 39 TIO No port assigned DSP56002/D, Rev. 3 C PC0 MOTOROLA Packaging Pin-out and Package Information Table 3-2 DSP56002 Signal Identification by PQFP Pin Number Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 1 EXTAL 26 TXD/PC1 51 DR 2 VCCQ 27 GNDS 52 DSO 3 GNDQ 28 SCLK/PC2 53 DSI/OS0 4 HA2/PB10 29 SC0/PC3 54 BS 5 GNDH 30 VCCS 55 X/Y 6 HA1/PB9 31 SCK/PC6 56 GNDA 7 HA0/PB8 32 SC2/PC5 57 DS 8 HACK/PB14 33 STD/PC8 58 VCCA 9 VCCH 34 GNDS 59 PS 10 HEN/PB12 35 SC1/PC4 60 A0 11 GNDH 36 GNDQ 61 A1 12 HR/W/PB11 37 VCCQ 62 GNDA 13 HREQ/PB13 38 SRD/PC7 63 A2 14 H7/PB7 39 TIO* 64 A3 15 H6/PB6 40 NC 65 A4 16 GNDH 41 BN 66 VCCQ 17 H5/PB5 42 WT 67 GNDQ 18 H4/PB4 43 BG 68 A5 19 H3/PB3 44 BR 69 VCCA 20 VCCH 45 VCCC 70 GNDA 21 H2/PB2 46 WR 71 A6 22 GNDH 47 RD 72 A7 23 H1/PB1 48 GNDC 73 A8 24 H0/PB0 49 NC 74 A9 25 RXD/PC0 50 DSCK/OS1 75 GNDA MOTOROLA DSP56002/D, Rev. 3 3-5 Packaging Pin-out and Package Information Table 3-2 DSP56002 Signal Identification by PQFP Pin Number (Continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 76 A10 95 D8 114 D20 77 A11 96 D9 115 D21 78 A12 97 VCCQ 116 GNDD 79 VCCA 98 GNDQ 117 D22 80 A13 99 GNDD 118 D23 81 GNDA 100 D10 119 MODC/NMI 82 A14 101 D11 120 MODB/IRQB 83 A15 102 VCCD 121 MODA/IRQA 84 D0 103 D12 122 GNDCK 85 D1 104 D13 123 CKOUT 86 GNDD 105 GNDD 124 VCCCK 87 D2 106 D14 125 RESET 88 D3 107 D15 126 CKP 89 VCCD 108 D16 127 VCCP 90 D4 109 D17 128 PCAP 91 D5 110 GNDD 129 GNDP 92 GNDD 111 D18 130 PLOCK 93 D6 112 D19 131 PINIT 94 D7 113 VCCD 132 XTAL Note: 1. 2. 3-6 “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-3 DSP56002 PQFP Pin Identification by Signal Name Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. A0 60 D3 114 DSO 52 A1 61 D4 116 EXTAL 1 A2 63 D5 117 GNDA 56 A3 64 D6 119 GNDA 62 A4 65 D7 94 GNDA 70 A5 68 D8 95 GNDA 75 A6 71 D9 96 GNDA 81 A7 72 D10 100 GNDC 48 A8 73 D11 101 GNDCK 122 A9 74 D12 103 GNDD 86 A10 76 D13 104 GNDD 92 A11 77 D14 106 GNDD 99 A12 78 D15 107 GNDD 105 A13 80 D16 108 GNDD 110 A14 82 D17 109 GNDD 116 A15 83 D18 111 GNDH 5 BG 43 D19 112 GNDH 11 BN 41 D20 114 GNDH 16 BR 44 D21 115 GNDH 22 BS 54 D22 117 GNDP 129 CKOUT 123 D23 118 GNDQ 3 CKP 126 DR 51 GNDQ 36 D0 84 DS 57 GNDQ 67 D1 85 DSCK 50 GNDQ 98 D2 87 DSI 53 GNDS 27 MOTOROLA DSP56002/D, Rev. 3 3-7 Packaging Pin-out and Package Information Table 3-3 DSP56002 PQFP Pin Identification by Signal Name (Continued) 3-8 Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. GNDS 34 PB1 23 PLOCK 130 H0 24 PB2 21 PS 59 H1 23 PB3 19 RD 47 H2 21 PB4 18 RESET 125 H3 19 PB5 17 RXD 25 H4 18 PB6 15 SC0 29 H5 17 PB7 14 SC1 35 H6 15 PB8 7 SC2 32 H7 14 PB9 6 SCK 31 HA0 7 PB10 4 SCLK 28 HA1 6 PB11 12 SRD 38 HA2 4 PB12 10 STD 33 HACK 8 PB13 13 TIO 39 HEN 10 PB14 8 TXD 26 HR/W 12 PC0 25 VCCA 58 HREQ 13 PC1 26 VCCA 69 IRQA 121 PC2 28 VCCA 79 IRQB 120 PC3 29 VCCC 45 MODA 121 PC4 35 VCCCK 124 MODB 120 PC5 32 VCCD 89 MODC 119 PC6 31 VCCD 102 NMI 119 PC7 38 VCCD 113 OS0 53 PC8 33 VCCH 9 OS1 50 PCAP 128 VCCH 20 PB0 24 PINIT 131 VCCP 127 VCCQ 2 VCCS 30 XTAL 132 VCCQ 37 WR 46 nc 40 VCCQ 66 WT 42 nc 49 VCCQ 97 X/Y 55 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Power and ground pins have special considerations for noise immunity. See Section 4 Design Considerations. Table 3-4 DSP56002 Power Supply Pins in PQFP Package Pin Number Power Supply Circuit Supplied 58 69 VCCA 79 Address Bus Buffers 56 62 70 GNDA 75 81 45 VCCC 48 GNDC 124 VCCCK 122 GNDCK Bus Control Buffers Clock 89 102 VCCD 113 86 92 99 GNDD Data Bus Buffers 105 110 116 9 20 VCCH 5 11 16 GNDH Host Interface Buffers 22 MOTOROLA DSP56002/D, Rev. 3 3-9 Packaging Pin-out and Package Information Table 3-4 DSP56002 Power Supply Pins in PQFP Package (Continued) Pin Number Power Supply Circuit Supplied 2 37 66 VCCQ 97 Internal Logic 3 36 67 GNDQ 98 127 VCCP 129 GNDP 30 VCCS 27 34 3-10 GNDS DSP56002/D, Rev. 3 PLL Serial Port MOTOROLA Packaging Pin-out and Package Information A 128X A1 AC AC S G X X=L, M, OR N S1 J J1 1 N 17 VIEW AB 117 18 116 CL VIEW AB B1 V1 PIN 1 IDENT M P B V BASE METAL AA L E P1 (D) AA 50 84 E1 D2 51 83 0.016 H L-M N 0.010 T L-M N 0.012 H L-M N 0.002 N 0.002 L-M 4X 2X PLATING SECTION AC-AC 4X 33 TIPS 4X 2X 0.004 T C C2 132X SEATING PLANE C1 T 132X D1 0.008 M T L-M N R R1 H K1 GAGE PLANE U K 132X D W θ 0.008 M T L-M N SECTION AA-AA CASE 831A-02 ISSUE C NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1982. 2. DIMENSIONS IN INCHES. 3. DIMENSIONS A, B, J, AND P DO NOT INCLUDE MOLD PROTRUSION. ALLOWABLE MOLD PROTRUSION FOR DIMENSIONS A AND B IS 0.007, FOR DIMENSIONS J AND P IS 0.010. 4. DATUM PLANE H IS LOCATED AT THE UNDERSIDE OF LEADS WHERE LEADS EXIT PACKAGE BODY. 5. DATUMS L, M, AND N TO BE DETERMINED WHERE CENTER LEADS EXIT PACKAGE BODY AT DATUM H. 6. DIMENSIONS S AND V TO BE DETERMINED AT SEATING PLANE, DATUM T. 7. DIMENSIONS A, B, J, AND P TO BE DETERMINED AT DATUM PLANE H. 8. DIMENSION F DOES NOT INCLUDE DAMBAR PROTRUSIONS. DAMBAR PROTRUSION SHALL NOT CAUSE THE LEAD WIDTH TO EXCEED 0.019. DIM A A1 B B1 C C1 C2 D D1 D2 E E1 F G J J1 K K1 P P1 R1 S S1 U V V1 W θ INCHES MIN MAX 1.100 BSC 0.550 BSC 1.100 BSC 0.550 BSC 0.160 0.180 0.020 0.040 0.135 0.145 0.008 0.012 0.012 0.016 0.008 0.011 0.006 0.008 0.005 0.007 0.014 0.014 0.025 BSC 0.950 BSC 0.475 BSC 0.034 0.044 0.010 BSC 0.950 BSC 0.475 BSC 0.013 REF 1.080 BSC 0.540 BSC 0.025 REF 1.080 BSC 0.540 BSC 0.006 0.008 0° 8° Figure 3-3 132-Pin Plastic Quad Flat Pack (PQFP) Mechanical Information MOTOROLA DSP56002/D, Rev. 3 3-11 Packaging Pin-out and Package Information TQFP Package Description 109 (Top View) Orientation Mark 1 37 NC DSCK/OS1 NC GNDC RD WR VCCC BR BG WT BN NC TIO SRD/PC7 VCCQ GNDQ SC1/PC4 NC GNDS STD/PC8 SC2/PC5 SCK/PC6 VCCS SC0/PC3 SCLK/PC2 GNDS TXD/PC1 RXD/PC0 H0/PB0 H1/PB1 GNDH H2/PB2 VCCH H3/PB3 H4/PB4 NC NC D22 D23 MODC/NMI MODB/IRQB MODA/IRQA GNDCK CKOUT VCCCK RESET CKP VCCP PCAP GNDP PLOCK PINIT XTAL NC EXTAL VCCQ GNDQ HA2/PB10 GNDH HA1/PB9 HA0/PB8 HACK/PB14 VCCH HEN/PB12 GNDH HR/W/PB11 HREQ/PB13 H7/PB7 H6/PB6 GNDH H5/PB5 NC NC D0 D1 GNDD D2 D3 VCCD D4 D5 GNDD D6 D7 D8 D9 VCCQ GNDQ GNDD D10 NC D11 VCCD D12 D13 GNDD D14 D15 D16 D17 GNDD D18 D19 VCCD D20 D21 GNDD NC 73 NC A15 A14 GNDA A13 VCCA A12 A11 A10 GNDA A9 A8 A7 A6 GNDA VCCA A5 NC GNDQ VCCQ A4 A3 A2 GNDA A1 A0 PS VCCA DS GNDA X/Y BS DSI/OS0 DSO DR NC Top and bottom views of the TQFP package are shown in Figure 3-4 and Figure 3-5 with their pin-outs. Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). 3. To simplify locating the pins, each fifth pin is shaded in the illustration. AA0613 Figure 3-4 Top View of the 144-pin Thin Quad Flat Pack (TQFP) Package 3-12 DSP56002/D, Rev. 3 MOTOROLA Packaging 109 (Bottom View) Orientation Mark (on Top Side) 1 37 NC D0 D1 GNDD D2 D3 VCCD D4 D5 GNDD D6 D7 D8 D9 VCCQ GNDQ GNDD D10 NC D11 VCCD D12 D13 GNDD D14 D15 D16 D17 GNDD D18 D19 VCCD D20 D21 GNDD NC NC H5/PB5 GNDH H6/PB6 H7/PB7 HREQ/PB13 HR/W/PB11 GNDH HEN/PB12 VCCH HACK/PB14 HA0/PB8 HA1/PB9 GNDH HA2/PB10 GNDQ VCCQ EXTAL NC XTAL PINIT PLOCK GNDP PCAP VCCP CKP RESET VCCCK CKOUT GNDCK MODA/IRQA MODB/IRQB MODC/NMI D23 D22 NC NC DSCK/OS1 NC GNDC RD WR VCCC BR BG WT BN NC TIO SRD/PC7 VCCQ GNDQ SC1/PC4 NC GNDS STD/PC8 SC2/PC5 SCK/PC6 VCCS SC0/PC3 SCLK/PC2 GNDS TXD/PC1 RXD/PC0 H0/PB0 H1/PB1 GNDH H2/PB2 VCCH H3/PB3 H4/PB4 NC 73 NC DR DSO DSI/OS0 BS X/Y GNDA DS VCCA PS A0 A1 GNDA A2 A3 A4 VCCQ GNDQ NC A5 VCCA GNDA A6 A7 A8 A9 GNDA A10 A11 A12 VCCA A13 GNDA A14 A15 NC Pin-out and Package Information Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). 3. To simplify locating the pins, each fifth pin is shaded in the illustration. AA0614 Figure 3-5 Bottom View of the144-pin Thin Quad Flat Pack (TQFP) Package MOTOROLA DSP56002/D, Rev. 3 3-13 Packaging Pin-out and Package Information The DSP56002 signals that may be programmed as General Purpose I/O are listed with their primary function in Table 3-9. Table 3-5 DSP56002 General Purpose I/O Pin Identification in TQFP Package 3-14 Pin Number Primary Function Port GPIO ID 44 H0 B PB0 43 H1 PB1 41 H2 PB2 39 H3 PB3 38 H4 PB4 35 H5 PB5 33 H6 PB6 32 H7 PB7 25 HA0 PB8 24 HA1 PB9 22 HA2 PB10 30 HR/W PB11 28 HEN PB12 31 HREQ PB13 26 HACK PB14 45 RXD 46 TXD PC1 48 SCLK PC2 49 SC0 PC3 56 SC1 PC4 52 SC2 PC5 51 SCK PC6 59 SRD PC7 53 STD PC8 60 TIO No port assigned DSP56002/D, Rev. 3 C PC0 MOTOROLA Packaging Pin-out and Package Information Table 3-6 DSP56002 Signal Identification by TQFP Pin Number Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 1 NC 26 HACK/PB14 51 SCK/PC6 2 D22 27 VCCH 52 SC2/PC5 3 D23 28 HEN/PB12 53 STD/PC8 4 MODC/NMI 29 GNDH 54 GNDS 5 MODB/IRQB 30 HR/W/PB11 55 NC 6 MODA/IRQA 31 HREQ/PB13 56 SC1/PC4 7 GNDCK 32 H7/PB7 57 GNDQ 8 CKOUT 33 H6/PB6 58 VCCQ 9 VCCCK 34 GNDH 59 SRD/PC7 10 RESET 35 H5/PB5 60 TIO 11 CKP 36 NC 61 NC 12 VCCP 37 NC 62 BN 13 PCAP 38 H4/PB4 63 WT 14 GNDP 39 H3/PB3 64 BG 15 PLOCK 40 VCCH 65 BR 16 PINIT 41 H2/PB2 66 VCCC 17 XTAL 42 GNDH 67 WR 18 NC 43 H1/PB1 68 RD 19 EXTAL 44 H0/PB0 69 GNDC 20 VCCQ 45 RXD/PC0 70 NC 21 GNDQ 46 TXD/PC1 71 DSCK/OS1 22 HA2/PB10 47 GNDS 72 NC 23 GNDH 48 SCLK/PC2 73 NC 24 HA1/PB9 49 SC0/PC3 74 DR 25 HA0/PB8 50 VCCS 75 DSO MOTOROLA DSP56002/D, Rev. 3 3-15 Packaging Pin-out and Package Information Table 3-6 DSP56002 Signal Identification by TQFP Pin Number (Continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 76 DSI/OS0 99 GNDA 122 D9 77 BS 100 A10 123 VCCQ 78 X/Y 101 A11 124 GNDQ 79 GNDA 102 A12 125 GNDD 80 DS 103 VCCA 126 D10 81 VCCA 104 A13 127 NC 82 PS 105 GNDA 128 D11 83 A0 106 A14 129 VCCD 84 A1 107 A15 130 D12 85 GNDA 108 NC 131 D13 86 A2 109 NC 132 GNDD 87 A3 110 D0 133 D14 88 A4 111 D1 134 D15 89 VCCQ 112 GNDD 135 D16 90 GNDQ 113 D2 136 D17 91 NC 114 D3 137 GNDD 92 A5 115 VCCD 138 D18 93 VCCA 116 D4 139 D19 94 GNDA 117 D5 140 VCCD 95 A6 118 GNDD 141 D20 96 A7 119 D6 142 D21 97 A8 120 D7 143 GNDD 98 A9 121 D8 144 NC Note: 1. 2. 3-16 “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-7 DSP56002 TQFP Pin Identification by Signal Name Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. A0 83 D3 114 DSO 75 A1 84 D4 116 EXTAL 19 A2 86 D5 117 GNDA 79 A3 87 D6 119 GNDA 85 A4 88 D7 120 GNDA 94 A5 92 D8 121 GNDA 99 A6 95 D9 122 GNDA 105 A7 96 D10 126 GNDC 69 A8 97 D11 128 GNDCK 7 A9 98 D12 130 GNDD 112 A10 100 D13 131 GNDD 118 A11 101 D14 133 GNDD 125 A12 102 D15 134 GNDD 132 A13 104 D16 135 GNDD 137 A14 106 D17 136 GNDD 143 A15 107 D18 138 GNDH 23 BG 64 D19 139 GNDH 29 BN 62 D20 141 GNDH 34 BR 65 D21 142 GNDH 42 BS 77 D22 2 GNDP 14 CKOUT 8 D23 3 GNDQ 21 CKP 11 DR 74 GNDQ 57 D0 110 DS 80 GNDQ 90 D1 111 DSCK 71 GNDQ 124 D2 113 DSI 76 GNDS 47 MOTOROLA DSP56002/D, Rev. 3 3-17 Packaging Pin-out and Package Information Table 3-7 DSP56002 TQFP Pin Identification by Signal Name (Continued) 3-18 Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. GNDS 54 PB1 43 PLOCK 15 H0 44 PB2 41 PS 82 H1 43 PB3 39 RD 68 H2 41 PB4 38 RESET 10 H3 39 PB5 35 RXD 45 H4 38 PB6 33 SC0 49 H5 35 PB7 32 SC1 56 H6 33 PB8 25 SC2 52 H7 32 PB9 24 SCK 51 HA0 25 PB10 22 SCLK 48 HA1 24 PB11 30 SRD 59 HA2 22 PB12 28 STD 53 HACK 26 PB13 31 TIO 60 HEN 28 PB14 26 TXD 46 HR/W 30 PC0 45 VCCA 81 HREQ 31 PC1 46 VCCA 93 IRQA 6 PC2 48 VCCA 103 IRQB 5 PC3 49 VCCC 66 MODA 6 PC4 56 VCCCK 9 MODB 5 PC5 52 VCCD 115 MODC 4 PC6 51 VCCD 129 NMI 4 PC7 59 VCCD 140 OS0 76 PC8 53 VCCH 27 OS1 71 PCAP 13 VCCH 40 PB0 44 PINIT 16 VCCP 12 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-7 DSP56002 TQFP Pin Identification by Signal Name (Continued) Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. VCCQ 20 XTAL 17 nc 72 VCCQ 58 nc 70 nc 73 VCCQ 89 nc 1 nc 91 VCCQ 123 nc 18 nc 108 VCCS 50 nc 36 nc 109 WR 67 nc 37 nc 127 WT 63 nc 55 nc 144 X/Y 78 nc 61 MOTOROLA DSP56002/D, Rev. 3 3-19 Packaging Pin-out and Package Information Power and ground pins have special considerations for noise immunity. See the section Design Considerations. Table 3-8 DSP56002 Power Supply Pins in TQFP Package Pin Number Power Supply Circuit Supplied 81 93 VCCA 103 Address Bus Buffers 79 85 94 GNDA 99 105 66 VCCC 69 GNDC 9 VCCCK 7 GNDCK 115 129 Bus Control Buffers Clock VCCD 140 112 118 125 GNDD Data Bus Buffers 132 137 143 27 40 VCCH 23 29 34 GNDH Host Interface Buffers 42 3-20 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-8 DSP56002 Power Supply Pins in TQFP Package (Continued) Pin Number Power Supply Circuit Supplied 20 58 89 VCCQ 123 Internal Logic 21 57 90 GNDQ 124 12 VCCP 14 GNDP 50 VCCS 47 54 MOTOROLA GNDS DSP56002/D, Rev. 3 PLL Serial Port 3-21 Packaging Pin-out and Package Information 0.20 T L-M N 4X PIN 1 IDENT 0.20 T L-M N 4X 36 TIPS 144 109 108 1 4X J1 P J1 M L CL B V 140X B1 V1 VIEW Y 36 VIEW Y 73 NOTES: 9. DIMENSIONS AND TOLERANCING PER ASME Y14.5, 1994. 10.DIMENSIONS IN MILLIMETERS. 11.DATUMS L, M AND N TO BE DETERMINED AT THE SEATING PLANE, DATUM T. 12.DIMENSIONS S AND V TO BE DETERMINED AT SEATING PLANE, DATUM T. 13.DIMENSIONS A AND B DO NOT INCULDE MOLD PROTRUSION. ALLOWABLE PROTRUSION IS 0.25 PER SIDE. DIMENSIONS A AND B DO INCLUDE MOLD MISMATCH AND ARE DETERMINED AT DATUM PLANE H. 14.DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLED DAMBAR PROTRUSION SHALL NOT CAUSE THE D DIMENSION TO EXCEED 0.35. 72 37 N A1 S1 A S VIEW AB C 0.1 T θ2 144X SEATING PLANE θ2 T PLATING J F AA C2 — 0.05 R2 θ R1 D 0.08 M 0.25 BASE METAL GAGE PLANE T L-M N SECTION J1-J1 (ROTATED 90) 144 PL (K) C1 E (Y) VIEW AB X X=L, M OR N G θ1 DIM A A1 B B1 C C1 C2 D E F G J K P R1 R2 S S1 V V1 Y Z AA θ θ1 θ2 MILLIMETERS MIN MAX 20.00 BSC 10.00 BSC 20.00 BSC 10.00 BSC 1.40 1.60 0.05 0.15 1.35 1.45 0.17 0.27 0.45 0.75 0.17 0.23 0.50 BSC 0.09 0.20 0.50 REF 0.25 BSC 0.13 0.20 0.13 0.20 22.00 BSC 11.00 BSC 22.00 BSC 11.00 BSC 0.25 REF 1.00 REF 0.09 0.16 0° 0° 7° 11° 13° (Z) CASE 918-03 ISSUE C Figure 3-6 144-pin Thin Plastic Quad Flat Pack (TQFP) Mechanical Information 3-22 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information PGA Package Description Top and bottom views of the PGA package are shown in Figure 3-7 and Figure 3-8 with their pin-outs. Orientation Mark 1 2 3 4 5 6 7 8 9 10 11 12 13 GNDQ VCCQ GNDQ VCCQ GNDQ VCCQ GNDQ VCCQ HA2 HACK H6 GNDH GNDH GNDD VCCCK RESET CKP VCCP PCAP PLOCK XTAL HA1 HEN H7 H5 VCCH VCCD MODB/ MODA/ GNDCK CKOUT GNDP IRQA IRQB PINIT EXTAL HA0 HREQ H2 RXD GNDH HR/W H4 H1 TXD VCCH H3 H0 SCLK GNDH A B C D GNDD D20 D21 D23 GNDD D18 D19 D22 D15 D16 D17 SC0 SCK SC2 D14 D13 D12 STD SC1 SRD D11 D10 D9 TIO NC BN VCCD D8 D7 A15 RD WR WT GNDS GNDD D6 D5 A14 A11 A0 X/Y DR BG VCCS GNDD D4 D3 A13 A10 A8 A6 A3 A1 DS DSO BR GNDS VCCD D2 D1 A12 A9 A7 A5 A4 A2 PS DSI/OS0 NC VCCC GNDD D0 GNDA VCCA GNDA GNDA VCCA GNDA VCCA GNDA BS DSCK/ OS1 GNDC MODC/ NMI E F G H Top View J K L M N Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). AA0615 Figure 3-7 Top View of the 132-pin Ceramic (RC) 13 ×13 Pin Grid Array Package MOTOROLA DSP56002/D, Rev. 3 3-23 Packaging Pin-out and Package Information Orientation Mark (on Top Side) 13 12 11 10 9 8 7 6 5 4 3 2 1 GNDH GNDH H6 HACK HA2 VCCQ GNDQ VCCQ GNDQ VCCQ GNDQ VCCQ GNDQ VCCH H5 H7 HEN HA1 XTAL PLOCK PCAP VCCP CKP RESET VCCCK GNDD GNDH RXD H2 HREQ HA0 EXTAL PINIT GNDP CKOUT GNDCK MODA/ MODB/ IRQA IRQB VCCD VCCH TXD H1 H4 HR/W GNDH SCLK H0 H3 SC2 SCK SRD A B C D D23 D21 D20 GNDD D22 D19 D18 GNDD SC0 D17 D16 D15 SC1 STD D12 D13 D14 BN NC TIO D9 D10 D11 GNDS WT WR RD A15 D7 D8 VCCD VCCS BG DR X/Y A0 A11 A14 D5 D6 GNDD GNDS BR DSO DS A1 A3 A6 A8 A10 A13 D3 D4 GNDD VCCC NC DSI/OS0 PS A2 A4 A5 A7 A9 A12 D1 D2 VCCD GNDC DSCK/ OS1 BS GNDA VCCA GNDA VCCA GNDA GNDA VCCA GNDA D0 GNDD MODC/ NMI E F G H Bottom View J K L M N Note: 1. “NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. 2. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). AA0616 Figure 3-8 Bottom View of the 132-pin Ceramic (RC) 13 ×13 Pin Grid Array Package 3-24 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information The DSP56008 signals that may be programmed as General Purpose I/O are listed with their primary function in Table 3-9. Table 3-9 DSP56002 General Purpose I/O Pin Identification in PGA Package MOTOROLA Pin Number Primary Function Port GPIO ID E11 H0 B PB0 D11 H1 PB1 C11 H2 PB2 E10 H3 PB3 D10 H4 PB4 B12 H5 PB5 A11 H6 PB6 B11 H7 PB7 C9 HA0 PB8 B9 HA1 PB9 A9 HA2 PB10 D9 HR/W PB11 B10 HEN PB12 C10 HREQ PB13 A10 HACK PB14 C12 RXD D12 TXD PC1 E12 SCLK PC2 F11 SC0 PC3 G12 SC1 PC4 F13 SC2 PC5 F12 SCK PC6 G13 SRD PC7 G11 STD PC8 H11 TIO No port assigned DSP56002/D, Rev. 3 C PC0 3-25 Packaging Pin-out and Package Information Table 3-10 DSP56002 Signal Identification by PGA Pin Number 3-26 Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name A1 GNDQ B13 VCCH E2 D18 A2 VCCQ C1 VCCD E3 D19 A3 GNDQ C2 MODB/IRQB E4 D22 A4 VCCQ C3 MODA/IRQA E10 H3/PB3 A5 GNDQ C4 GNDCK E11 H0/PB0 A6 VCCQ C5 CKOUT E12 SCLK/PC2 A7 GNDQ C6 GNDP E13 GNDH A8 VCCQ C7 PINIT F1 D15 A9 HA2/PB10 C8 EXTAL F2 D16 A10 HACK/PB14 C9 HA0/PB8 F3 D17 A11 H6/PB6 C10 HREQ/PB13 F11 SC0/PC3 A12 GNDH C11 H2/PB2 F12 SCK/PC6 A13 GNDH C12 RXD/PC0 F13 SC2/PC5 B1 GNDD C13 GNDH G1 D14 B2 VCCCK D1 GNDD G2 D13 B3 RESET D2 D20 G3 D12 B4 CKP D3 D21 G11 STD/PC8 B5 VCCP D4 D23 G12 SC1/PC4 B6 PCAP D5 MODC/NMI G13 SRD/PC7 B7 PLOCK D9 HR/W/PB11 H1 D11 B8 XTAL D10 H4/PB4 H2 D10 B9 HA1/PB9 D11 H1/PB1 H3 D9 B10 HEN/PB12 D12 TXD/PC1 H11 TIO* B11 H7/PB7 D13 VCCH H12 NC B12 H5/PB5 E1 GNDD H13 BN DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-10 DSP56002 Signal Identification by PGA Pin Number (Continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name J1 VCCD L2 D4 M8 A4 J2 D8 L3 D3 M9 A2 J3 D7 L4 A13 M10 PS J4 A15 L5 A10 M11 DSI/OS0 J10 RD L6 A8 M12 NC J11 WR L7 A6 M13 VCCC J12 WT L8 A3 N1 GNDD J13 GNDS L9 A1 N2 D0 K1 GNDD L10 DS N3 GNDA K2 D6 L11 DSO N4 VCCA K3 D5 L12 BR N5 GNDA K4 A14 L13 GNDS N6 GNDA K5 A11 M1 VCCD N7 VCCA K9 A0 M2 D2 N8 GNDA K10 X/Y M3 D1 N9 VCCA K11 DR M4 A12 N10 GNDA K12 BG M5 A9 N11 BS K13 VCCS M6 A7 N12 DSCK/OS1 L1 GNDD M7 A5 N13 GNDC Note: 1. 2. MOTOROLA NC” are No Connection pins that are reserved for possible future enhancements. Do not connect these pins to any power, ground, signal traces, or vias. An OVERBAR indicates the signal is asserted when the voltage = ground (active low). DSP56002/D, Rev. 3 3-27 Packaging Pin-out and Package Information Table 3-11 DSP56002 PGA Pin Identification by Signal Name 3-28 Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. A0 K9 D3 L3 DSO L11 A1 L9 D4 L2 EXTAL C8 A2 M9 D5 K3 GNDA N10 A3 L8 D6 K2 GNDA N8 A4 M8 D7 J3 GNDA N6 A5 M7 D8 J2 GNDA N5 A6 L7 D9 H3 GNDA N3 A7 M6 D10 H2 GNDC N13 A8 L6 D11 H1 GNDCK C4 A9 M5 D12 G3 GNDD N1 A10 L5 D13 G2 GNDD L1 A11 K5 D14 G1 GNDD K1 A12 M4 D15 F1 GNDD E1 A13 L4 D16 F2 GNDD D1 A14 K4 D17 F3 GNDD B1 A15 J4 D18 E2 GNDH A12 BG K12 D19 E3 GNDH A13 BN H13 D20 D2 GNDH C13 BR L12 D21 D3 GNDH E13 BS N11 D22 E4 GNDP C6 CKOUT C5 D23 D4 GNDQ A1 CKP B4 DR K11 GNDQ A2 D0 N2 DS L10 GNDQ A5 D1 M3 DSCK N12 GNDQ A7 D2 M2 DSI M11 GNDS J13 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-11 DSP56002 PGA Pin Identification by Signal Name (Continued) Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. GNDS L13 PB5 B12 SCK F12 H0 E11 PB6 A11 SCLK E12 H1 D11 PB7 B11 SRD G13 H2 C11 PB8 C9 STD G11 H3 E10 PB9 B9 TIO H11 H4 D10 PB10 A9 TXD D12 H5 B12 PB11 D9 VCCA N9 H6 A11 PB12 B10 VCCA N7 H7 B11 PB13 C10 VCCA N4 HA0 C9 PB14 A10 VCCC M13 HA1 B9 PC0 C12 VCCCK B2 HA2 A9 PC1 D12 VCCD M1 HACK A10 PC2 E12 VCCD J1 HEN B10 PC3 F11 VCCD C1 HR/W D9 PC4 G12 VCCH B13 HREQ C10 PC5 F13 VCCH D13 IRQA C3 PC6 F12 VCCP B5 IRQB C2 PC7 G13 VCCQ A2 MODA C3 PC8 G11 VCCQ A4 MODB C2 PCAP B6 VCCQ A6 MODC D5 PINIT C7 VCCQ A8 NMI D5 PLOCK B7 VCCS K13 OS0 M11 PS M10 WR J11 OS1 N12 RD J10 WT J12 PB0 E11 RESET B3 X/Y K10 PB1 D11 RXD C12 XTAL B8 PB2 C11 SC0 F11 nc H12 PB3 E10 SC1 G12 nc M12 PB4 D10 SC2 F13 MOTOROLA DSP56002/D, Rev. 3 3-29 Packaging Pin-out and Package Information Power and ground pins have special considerations for noise immunity. See the section Design Considerations. Table 3-12 DSP56002 Power Supply Pins in PGA Package Pin Number Power Supply Circuit Supplied N9 N7 VCCA N4 Address Bus Buffers N10 N8 N6 GNDA N5 N3 M13 VCCC N13 GNDC B2 VCCCK C4 GNDCK M1 J1 Bus Control Buffers Clock VCCD C1 N1 L1 K1 GNDD Data Bus Buffers E1 D1 B1 B13 D13 VCCH A12 A13 C13 GNDH Host Interface Buffers E13 3-30 DSP56002/D, Rev. 3 MOTOROLA Packaging Pin-out and Package Information Table 3-12 DSP56002 Power Supply Pins in PGA Package (Continued) Pin Number Power Supply Circuit Supplied A8 A6 VCCQ A4 A2 Internal Logic A1 A2 GNDQ A5 A7 B5 VCCP C6 GNDP K13 VCCS J13 PLL Serial Port GNDS L13 -TK -A- G N M L K J H G F E D C B A G NOTES: 1. 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. 2. CONTROLLING DIMENSION: INCH. DIM A B C D G K INCHES MIN MAX 1.340 1.380 1.340 1.380 0.100 0.150 0.017 0.022 0.100 BSC 0.170 0.195 1 2 3 4 5 6 7 8 9 10 11 12 13 -BC D 132 PL 0.005 M T A S B S CASE 789B-01 ISSUE O Figure 3-9 132-pin Ceramic Pin Grid Array (PGA) Package Mechanical Information MOTOROLA DSP56002/D, Rev. 3 3-31 Packaging Ordering Drawings ORDERING DRAWINGS Complete mechanical information regarding DSP56002 packaging is available by facsimile through Motorola's Mfax™ system. Call the following number to obtain information by facsimile: (602) 244-6591 The Mfax automated system requests the following information: • The receiving facsimile telephone number including area code or country code • The caller’s Personal Identification Number (PIN) Note: For first time callers, the system provides instructions for setting up a PIN, which requires entry of a name and telephone number. • The type of information requested: – Instructions for using the system – A literature order form – Specific part technical information or data sheets – Other information described by the system messages A total of three documents may be ordered per call. The DSP56002 132-pin PQFP package mechanical drawing is referenced as 831A-02. The reference number for the 144-pin TQFP package is 918-03. The reference number for the 132-pin ceramic PGA package is 789B-01. 3-32 DSP56002/D, Rev. 3 MOTOROLA SECTION 4 DESIGN CONSIDERATIONS HEAT DISSIPATION An estimation of the chip junction temperature, TJ, in °C can be obtained from the equation: Equation 1: T J = T A + ( P D × R θJA ) Where: TA = ambient temperature ˚C RθJA = package junction-to-ambient thermal resistance ˚C/W PD = power dissipation in package Historically, thermal resistance has been expressed as the sum of a junction-to-case thermal resistance and a case-to-ambient thermal resistance: Equation 2: R θJA = R θJC + R θCA Where: RθJA = package junction-to-ambient thermal resistance ˚C/W RθJC = package junction-to-case thermal resistance ˚C/W RθCA = package case-to-ambient thermal resistance ˚C/W RθJC is device-related and cannot be influenced by the user. The user controls the thermal environment to change the case-to-ambient thermal resistance, RθCA. For example, the user can change the air flow around the device, add a heat sink, change the mounting arrangement on the Printed Circuit Board, or otherwise change the thermal dissipation capability of the area surrounding the device on a Printed Circuit Board. This model is most useful for ceramic packages with heat sinks; some 90% of the heat flow is dissipated through the case to the heat sink and out to the ambient environment. For ceramic packages, in situations where the heat flow is split between a path to the case and an alternate path through the Printed Circuit Board, analysis of the device thermal performance may need the additional modeling capability of a system level thermal simulation tool. The thermal performance of plastic packages is more dependent on the temperature of the Printed Circuit Board to which the package is mounted. Again, if the MOTOROLA DSP56002/D, Rev. 3 4-1 Design Considerations Heat Dissipation estimations obtained from RθJA do not satisfactorily answer whether the thermal performance is adequate, a system level model may be appropriate. A complicating factor is the existence of three common ways for determining the junction-to-case thermal resistance in plastic packages: • To minimize temperature variation across the surface, the thermal resistance is measured from the junction to the outside surface of the package (case) closest to the chip mounting area when that surface has a proper heat sink. • To define a value approximately equal to a junction-to-board thermal resistance, the thermal resistance is measured from the junction to where the leads are attached to the case. • If the temperature of the package case (TT) as determined by a thermocouple, the thermal resistance is computed using the value obtained by the equation (TJ – TT)/PD. As noted above, the junction-to-case thermal resistances quoted in this data sheet are determined using the first definition. From a practical standpoint, that value is also suitable for determining the junction temperature from a case thermocouple reading in forced convection environments. In natural convection, using the junction-to-case thermal resistance to estimate junction temperature from a thermocouple reading on the case of the package will estimate a junction temperature slightly hotter than actual temperature. Hence, the new thermal metric, Thermal Characterization Parameter or ΨJT, has been defined to be (TJ – TT)/PD. This value gives a better estimate of the junction temperature in natural convection when using the surface temperature of the package. Remember that surface temperature readings of packages are subject to significant errors caused by inadequate attachment of the sensor to the surface and to errors caused by heat loss to the sensor. The recommended technique is to attach a 40-gauge thermocouple wire and bead to the top center of the package with thermally conductive epoxy. Note: Table 2-2 Thermal Characteristics on page 2-2 contains the package thermal values for this chip. 4-2 DSP56002/D, Rev. 3 MOTOROLA Design Considerations Electrical Design Considerations ELECTRICAL DESIGN CONSIDERATIONS CAUTION This device contains protective circuitry to guard against damage due to high static voltage or electrical fields. However, normal precautions are advised to avoid application of any voltages higher than maximum rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused inputs are tied to an appropriate logic voltage level (e.g., either GND or VCC). Use the following list of recommendations to assure correct DSP operation: MOTOROLA • Provide a low-impedance path from the board power supply to each VCC pin on the DSP, and from the board ground to each GND pin. • Use at least four 0.1 µF bypass capacitors positioned as close as possible to the four sides of the package to connect the VCC power source to GND. • Ensure that capacitor leads and associated printed circuit traces that connect to the chip VCC and GND pins are less than 0.5 inch per capacitor lead. • Use at least a four-layer Printed Circuit Board (PCB) with two inner layers for VCC and GND. • Because the DSP output signals have fast rise and fall times, PCB trace lengths should be minimal. This recommendation particularly applies to the address and data buses as well as the RD, WR, IRQA, IRQB, NMI, HEN, and HACK pins. • Consider all device loads as well as parasitic capacitance due to PCB traces when calculating capacitance. This is especially critical in systems with higher capacitive loads that could create higher transient currents in the VCC and GND circuits. • All inputs must be terminated (i.e., not allowed to float) using CMOS levels. • Take special care to minimize noise levels on the PLL supply pins (both VCC and GND). DSP56002/D, Rev. 3 4-3 Design Considerations Power Consumption POWER CONSUMPTION Power dissipation is a key issue in portable DSP applications. The following describes some factors which affect current consumption. Current consumption is described by the formula: Equation 3: I = C × V × f where: C = node/pin capacitance V = voltage swing f = frequency of node/pin toggle For example, for an address pin loaded with a 50 pF capacitance and operating at 5.5 V with a 40 MHz clock, toggling at its maximum possible rate (which is 10 MHz), the current consumption is: Equation 4: I = 50 × 10 –12 × 5.5 × 10 × 10 6 = 2.75mA The maximum internal current value (ICCI-max), reflects the maximum ICC expected when running the code given below. This represents “typical” internal activity, and is included as a point of reference. Some applications may consume more or less current depending on the code used. The typical internal current value (ICCI-typ) reflects what is typically seen when running the given code. The following steps are recommended for applications requiring very low current consumption: 1. Minimize external memory accesses; use internal memory accesses instead. 2. Minimize the number of pins that are switching. 3. Minimize the capacitive load on the pins. 4. Connect the unused inputs to pull-up or pull-down resistors. 4-4 DSP56002/D, Rev. 3 MOTOROLA Design Considerations Power Consumption Current consumption test code: TP1 MOTOROLA org jmp org movep move move move move nop rep move rep mov clr move rep mac move jmp nop jmp p:RESET MAIN p:MAIN #$180000,x:$FFFD #0,r0 #0,r4 #$00FF, m0 #$00FF, m4 #256 r0,x:(r0)+ #256 r4,y:(r4)+ a l:(r0)+,a #30 x0,y0,a x:(r0)+,x0 y:(r4)+,y0 a,p:(r5) TP1 MAIN DSP56002/D, Rev. 3 4-5 Design Considerations Host Port Considerations HOST PORT CONSIDERATIONS Careful synchronization is required when reading multibit registers that are written by another asynchronous system. This is a common problem when two asynchronous systems are connected. The situation exists in the host interface. The following paragraphs present considerations for proper operation. Host Programming Considerations UNSYNCHRONIZED READING OF RECEIVE BYTE REGISTERS When reading receive byte registers (RXH, RXM, and RXL) the host programmer should use interrupts or poll the RXDF flag that indicates that data is available. This assures that the data in the receive byte registers will be stable. OVERWRITING TRANSMIT BYTE REGISTERS The host programmer should not write to the transmit byte registers (TXH, TXM, and TXL) unless the TXDE bit is set indicating that the transmit byte registers are empty. This guarantees that the transmit byte registers will transfer valid data to the HRX register. SYNCHRONIZATION OF STATUS BITS FROM DSP TO HOST HC, HREQ, DMA, HF3, HF2, TRDY, TXDE, and RXDF status bits are set or cleared from inside the DSP and read by the host processor. The host can read these status bits very quickly without regard to the clock rate used by the DSP, but the possibility exists that the state of the bit could be changing during the read operation. This is generally not a system problem, since the bit will be read correctly in the next pass of any host polling routine. Note: Refer to DSP56002 User’s Manual sections describing the I/O Interface and Host/DMA Interface Programming Model for descriptions of these status bits. OVERWRITING THE HOST VECTOR The Host programmer should change the Host Vector register only when the Host Command bit (HC) is clear. This change guarantees that the DSP interrupt control logic will receive a stable vector. 4-6 DSP56002/D, Rev. 3 MOTOROLA Design Considerations Host Port Considerations CANCELLING A PENDING HOST COMMAND EXCEPTION The host processor may elect to clear the HC bit to cancel the Host Command Exception request at any time before it is recognized by the DSP. Because the host does not know exactly when the exception will be recognized (due to exception processing synchronization and pipeline delays), the DSP may execute the Host Command Exception after the HC bit is cleared. For these reasons, the HV bits must not be changed at the same time the HC bit is cleared. VARIANCE IN THE HI TIMING HI timing may vary during initial startup during the time after reset before the PLL locks. Therefore, before a host attempt to load (i.e., bootstrap) the DSP, the host should first make sure that the HI port programming has been completed. The following steps can be used to ensure that the programming is complete: 1. Set the INIT bit in the ICR 2. Poll the INIT bit until it is cleared. 3. Read the ISR. An alternate method is: 1. Write the TREQ/RREQ together with INIT. 2. Poll INIT, ISR, and the HREQ pin. DSP Programming Considerations SYNCHRONIZATION OF STATUS BITS FROM HOST TO DSP DMA, HF1, HF0, and HCP, HTDE, and HRDF status bits are set or cleared by the host processor side of the interface. These bits are individually synchronized to the DSP clock. Note: Refer to DSP56002 User’s Manual sections describing the I/O Interface and Host/DMA Interface Programming Model for descriptions of these status bits. READING HF0 AND HF1 AS AN ENCODED PAIR A potential problem exists when reading status bits HF0 and HF1 as an encoded pair (i.e., the four combinations 00, 01, 10, and 11 each have significance). A very small probability exists that the DSP will read the status bits synchronized during transition. The solution to this potential problem is to read the HF0 and HF1 bits twice and check for consensus. MOTOROLA DSP56002/D, Rev. 3 4-7 Design Considerations Package Compatibility PACKAGE COMPATIBILITY The PQFP and TQFP packages are designed so that a single Printed Circuit Board (PCB) can accommodate either package. The two package pinouts are similarly sequenced. Proper orientation of each package with the smaller TQFP footprint inside the PQFP footprint allow connection of PCB traces to either package. For example, the D0 pin is near the corner of both the PQFP package (pin 84) and the TQFP package (pin 109), and is adjacent to D1 on both packages. Note: Some “no connect” pins in the TQFP pin sequence are excluded from the PQFP pin sequence. 4-8 DSP56002/D, Rev. 3 MOTOROLA SECTION 5 ORDERING INFORMATION DSP56002 ordering information in the table below lists the pertinent information needed to place an order. Consult a Motorola Semiconductor sales office or authorized distributor to determine availability and to order parts. Table 5-1 DSP56002 Ordering Information Part Supply Voltage Package Type Plastic Quad Flat Pack (PQFP) DSP56002 MOTOROLA 5V Pin Count 132 Plastic Thin Quad Flat Pack (TQFP) 144 Ceramic Pin Grid Array 132 DSP56002/D, Rev. 3 Frequency (MHz) Order Number 40 DSP56002FC40 66 DSP56002FC66 80 DSP56002FC80 40 DSP56002PV40 66 DSP56002PV66 80 DSP56002PV80 40 DSP56002RC40 5-1 OnCE and Mfax are trademarks of Motorola, Inc. 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