INTEGRATED CIRCUITS DATA SHEET PCF8584 I2C-bus controller Product specification Supersedes data of 1997 Mar 19 File under Integrated Circuits, IC12 1997 Oct 21 Philips Semiconductors Product specification I2C-bus controller PCF8584 CONTENTS 7 SOFTWARE FLOWCHART EXAMPLES 1 FEATURES 7.1 7.2 Initialization Implementation 2 GENERAL DESCRIPTION 8 I2C-BUS TIMING DIAGRAMS 3 ORDERING INFORMATION 9 LIMITING VALUES 4 BLOCK DIAGRAM 10 HANDLING 5 PINNING 11 DC CHARACTERISTICS 6 FUNCTIONAL DESCRIPTION 12 I2C-BUS TIMING SPECIFICATIONS 6.1 6.2 6.3 6.4 6.5 6.6 6.7 6.8 6.8.1 6.8.1.1 6.8.1.2 6.8.1.3 6.8.1.4 6.8.1.5 6.8.1.6 6.8.2 6.8.2.1 6.8.2.2 6.8.2.3 6.8.2.4 6.8.2.5 6.8.2.6 6.8.2.7 6.9 6.10 6.11 6.11.1 6.11.2 6.12 6.12.1 6.12.2 6.12.3 General Interface Mode Control (IMC) Set-up registers S0', S2 and S3 Own address register S0' Clock register S2 Interrupt vector S3 Data shift register/read buffer S0 Control/status register S1 Register S1 control section PIN (Pending Interrupt Not) ESO (Enable Serial Output) ES1 and ES2 ENI STA and STO ACK Register S1 status section PIN bit STS BER LRB/AD0 AAS LAB BB Multi-master operation Reset Comparison to the MAB8400 I2C-bus interface Deleted functions added functions Special function modes Strobe Long-distance mode Monitor mode 13 PARALLEL INTERFACE TIMING 14 APPLICATION INFORMATION 14.1 Application Notes 15 PACKAGE OUTLINES 16 SOLDERING 16.1 16.2 16.2.1 16.2.2 16.3 16.3.1 16.3.2 16.3.3 Introduction DIP Soldering by dipping or by wave Repairing soldered joints SO Reflow soldering Wave soldering Repairing soldered joints 17 DEFINITIONS 18 LIFE SUPPORT APPLICATIONS 1997 Oct 21 19 PURCHASE OF PHILIPS I2C COMPONENTS 2 Philips Semiconductors Product specification I2C-bus controller 1 PCF8584 FEATURES • Parallel-bus to 2 I2C-bus protocol converter and interface GENERAL DESCRIPTION The PCF8584 is an integrated circuit designed in CMOS technology which serves as an interface between most standard parallel-bus microcontrollers/microprocessors and the serial I2C-bus. The PCF8584 provides both master and slave functions. • Compatible with most parallel-bus microcontrollers/microprocessors including 8049, 8051, 6800, 68000 and Z80 • Both master and slave functions Communication with the I2C-bus is carried out on a byte-wise basis using interrupt or polled handshake. It controls all the I2C-bus specific sequences, protocol, arbitration and timing. The PCF8584 allows parallel-bus systems to communicate bidirectionally with the I2C-bus. • Automatic detection and adaption to bus interface type • Programmable interrupt vector • Multi-master capability • I2C-bus monitor mode • Long-distance mode (4-wire) • Operating supply voltage 4.5 to 5.5 V • Operating temperature range: −40 to +85 °C. 3 ORDERING INFORMATION TYPE NUMBER PACKAGE NAME DESCRIPTION VERSION PCF8584P DIP20 plastic dual in-line package; 20 leads (300 mil) SOT146-1 PCF8584T SO20 plastic small outline package; 20 leads; body width 7.5 mm SOT163-1 1997 Oct 21 3 Philips Semiconductors Product specification I2C-bus controller 4 PCF8584 BLOCK DIAGRAM PARALLEL BUS handbook, full pagewidth SDA/ (3) SDA OUT 2 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 V DD V SS 15 14 13 12 11 9 8 7 20 10 MSB DIGITAL FILTER READ BUFFER read only DATA SHIFT REGISTER S0 AND READ BUFFER write only SHIFT REGISTER 8 DATA CONTROL X COMPARATOR S0, S0' (1) 8 MSB (1) LSB X OWN ADDRESS S0' 8 PCF8584 INTERRUPT VECTOR S3 SCL/ (3) SCL IN 3 DIGITAL FILTER CLOCK REGISTER S2 0 0 0 default: 00H 80XX 0FH 68XXX 8 S24 S23 S22 S21 S20 CLOCK REGISTER S2 8 REGISTER S1 CONTROL STATUS PIN SCL CONTROL ES0 ES1 ES2 ENI STA STO ACK write only CONTROL STATUS REGISTER S1 PIN CLOCK PRESCALER SCL MULTIPLEXER BUS BUSY LOGIC ARBITRATION LOGIC 19 RESET/ STROBE (O.C.) 17 CS 0 STS BER AD0/ LRB 6 A0 18 16 WR (R/W) (2) RD (DTACK) LAB BB read only REGISTER ACCESS CONTROL BUS BUFFER CONTROL INTERRUPT CONTROL RESET/STROBE CONTROL PARALLEL BUS CONTROL (2) 5 4 1 INT (3) SCL OUT IACK CLK (3) SDA IN MBD908 - 1 (1) X = don’t care. (2) Pin mnemonics between parenthesis indicate the 68000 mode pin designations. (3) These pin mnemonics represent the long-distance mode pin designations. Fig.1 Block diagram. 1997 Oct 21 AAS 4 Philips Semiconductors Product specification I2C-bus controller 5 PCF8584 PINNING SYMBOL PIN I/O DESCRIPTION CLK 1 I SDA or SDA OUT 2 I/O I2C-bus serial data input/output (open-drain). Serial data output in long-distance mode. SCL or SCL IN 3 I/O I2C-serial clock input/output (open-drain). Serial clock input in long-distance mode. IACK or SDA IN 4 I Interrupt acknowledge input (internal pull-up); when this signal is asserted the interrupt vector in register S3 will be available at the bus Port if the ENI flag is set. Serial data input in long-distance mode. INT or SCL OUT 5 O Interrupt output (open-drain); this signal is enabled by the ENI flag in register S1. It is asserted when the PIN flag is reset. (PIN is reset after 1 byte is transmitted or received over the I2C-bus). Serial clock output in long-distance mode. A0 6 I Register select input (internal pull-up); this input selects between the control/status register and the other registers. Logic 1 selects register S1, logic 0 selects one of the other registers depending on bits loaded in ESO, ES1 and ES2 of register S1. DB0 7 I/O bidirectional 8-bit bus Port 0 DB1 8 I/O bidirectional 8-bit bus Port 1 DB2 9 I/O bidirectional 8-bit bus Port 2 VSS 10 − DB3 11 I/O bidirectional 8-bit bus Port 3 DB4 12 I/O bidirectional 8-bit bus Port 4 DB5 13 I/O bidirectional 8-bit bus Port 5 DB6 14 I/O bidirectional 8-bit bus Port 6 DB7 15 I/O bidirectional 8-bit bus Port 7 RD (DTACK) 16 I/(O) CS 17 I chip select input (internal pull-up) WR (R/W) 18 I WR is the write control input for MAB8048, MAB8051, or Z80-types (internal pull-up). R/W control input for 68000-types. RESET/ STROBE 19 I/O VDD 20 − 1997 Oct 21 clock input from microcontroller clock generator (internal pull-up) ground RD is the read control input for MAB8049, MAB8051 or Z80-types. DTACK is the data transfer control output for 68000-types (open-drain). Reset input (open-drain); this input forces the I2C-bus controller into a predefined state; all flags are reset, except PIN, which is set. Also functions as strobe output. supply voltage 5 Philips Semiconductors Product specification I2C-bus controller PCF8584 Table 1 TYPE handbook, halfpage CLK 1 20 VDD SDA or SDA OUT 2 19 RESET / STROBE (1) SCL or SCL IN 3 18 WR (R/W) IACK or SDA IN 4 17 CS INT or SCL OUT 5 16 RD (DTACK) A0 6 15 DB7 DB0 7 14 DB6 DB1 8 13 DB5 DB2 9 12 DB4 VSS 10 11 DB3 (1) Pin mnemonics between parenthesis indicate the 68000 mode pin designations. R DTACK IACK 8048/ 8051 no yes yes no no 68000 yes no no yes yes Z80 no yes yes no yes Register S0 performs all serial-to-parallel interfacing with the I2C-bus. Fig.2 Pin configuration. Register S1 contains I2C-bus status information required for bus access and/or monitoring. FUNCTIONAL DESCRIPTION 6.2 General Interface Mode Control (IMC) Selection of either an 80XX mode or 68000 mode interface is achieved by detection of the first WR-CS signal sequence. The concept takes advantage of the fact that the write control input is common for both types of interfaces. An 80XX-type interface is default. If a HIGH-to-LOW transition of WR (R/W) is detected while CS is HIGH, the 68000-type interface mode is selected and the DTACK output is enabled. Care must be taken that WR and CS are stable after reset. The PCF8584 acts as an interface device between standard high-speed parallel buses and the serial I2C-bus. On the I2C-bus, it can act either as master or slave. Bidirectional data transfer between the I2C-bus and the parallel-bus microcontroller is carried out on a byte-wise basis, using either an interrupt or polled handshake. Interface to either 80XX-type (e.g. 8048, 8051, Z80) or 68000-type buses is possible. Selection of bus type is automatically performed (see Section 6.2). 1997 Oct 21 WR The remaining two registers function as double registers (data buffer/shift register S0, and control/status register S1) which are used during actual data transmission/reception. By using these double registers, which are separately write and read accessible, overhead for register access is reduced. Register S0 is a combination of a shift register and data buffer. MLA012 - 1 6.1 R/W The structure of the PCF8584 is similar to that of the I2C-bus interface section of the Philips’ MABXXXX/PCF84(C)XX-series of microcontrollers, but with a modified control structure. The PCF8584 has five internal register locations. Three of these (own address register S0', clock register S2 and interrupt vector S3) are used for initialization of the PCF8584. Normally they are only written once directly after resetting of the PCF8584. (1) PCF8584 6 Control signals utilized by the PCF8584 for microcontroller/microprocessor interfacing 6 Philips Semiconductors Product specification I2C-bus controller PCF8584 I2C-bus SCL (1.5 MHz) EN ENRD D EN D handbook, full pagewidth SIO DIVIDER (S21 and S20) DIVIDER (S24, S23, S22) /2, 3, 4, 5, 8 FILTER t = 16CLK MBE706 RESET STROBE CS A0 WR/ RD/ R/W DTACK INT IACK CLK (50 : 50) mode locked handbook, full pagewidth mode select R/W (1) CS DTACK mode select WR (2) CS MBE707 (1) Bus timing; 68000 mode write cycle. (2) Bus timing; 80XX mode. Fig.3 68000/80XX timing sequence utilized by the Interface Mode Control (IMC). 1997 Oct 21 7 Philips Semiconductors Product specification I2C-bus controller 6.3 PCF8584 Programming of S2 is accomplished via the parallel-bus when A0 = LOW, with the appropriate bit combinations set in control status register S1 (S1 is written when A0 = HIGH). Bit combinations for accessing all registers are given in Table 5. Set-up registers S0', S2 and S3 Registers S0', S2 and S3 are used for initialization of the PCF8584 (see Fig.5 ‘Initialization sequence’ flowchart). 6.4 Own address register S0' When the PCF8584 is addressed as slave, this register must be loaded with the 7-bit I2C-bus address to which the PCF8584 is to respond. During initialization, the own address register S0' must be written to, regardless whether it is later used. The Addressed As Slave (AAS) bit in status register S1 is set when this address is received (the value in S0 is compared with the value in S0'). Note that the S0 and S0' registers are offset by one bit; hence, programming the own address register S0' with a value of 55H will result in the value AAH being recognized as the PCF8584’s slave address (see Fig.1). Table 3 Programming of S0' is accomplished via the parallel-bus when A0 is LOW, with the appropriate bit combinations set in control status register S1 (S1 is written when pin A0 = HIGH). Bit combinations for accessing all registers are given in Table 5. After reset, S0' has default address 00H (PCF8584 is thus initially in monitor mode, see Section 6.12.3). Note 6.5 INTERNAL CLOCK FREQUENCY 6.6 S21 S20 0 0 90 0 1 45 1 0 11 1 1 1.5 0 X(1) 3 1 0 0 4.43 1 0 1 6 1 1 0 8 1 1 1 12 Interrupt vector S3 • Vector is ‘0FH’ in 68000 mode. On reset the PCF8584 is in the 80XX mode, thus the default interrupt vector is ‘00H’. 6.7 Data shift register/read buffer S0 Register S0 acts as serial shift register and read buffer interfacing to the I2C-bus. All read and write operations to/from the I2C-bus are done via this register. S0 is a combination of a shift register and a data buffer; parallel data is always written to the shift register, and read from the data buffer. I2C-bus data is always shifted in or out of shift register S0. S22, S23 and S24 are used for control of the internal clock prescaler. Due to the possibility of varying microcontroller clock signals, the prescaler can be programmed to adapt to 5 different clock rates, thus providing a constant internal clock. This is required to provide a stable time base for the SCL generator and the digital filters associated with the I2C-bus signals SCL and SDA. Selection for adaption to external clock rates is shown in Table 3. 1997 Oct 21 S22 X(1) • Vector is ‘00H’ in 80XX mode Register S2 selection of SCL frequency APPROXIMATE SCL FREQUENCY fSCL (kHz) S23 The interrupt vector register provides an 8-bit user-programmable vector for vectored-interrupt microcontrollers. The vector is sent to the bus port (DB7 to DB0) when an interrupt acknowledge signal is asserted and the ENI (enable interrupt) flag is set. Default vector values are: Register S2 provides control over chip clock frequency and SCL clock frequency. S20 and S21 provide a selection of 4 different I2C-bus SCL frequencies which are shown in Table 2. Note that these SCL frequencies are only obtained when bits S24, S23 and S22 are programmed to the correct input clock frequency (fclk). BIT fclk (MHz) S24 1. X = don’t care. Clock register S2 Table 2 Register S2 selection of clock frequency 8 Philips Semiconductors Product specification I2C-bus controller PCF8584 to/from microcontroller parallel bus andbook, full pagewidth DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 Read only Read Buffer Data Shift Register S0 and Read Buffer Shift register to/from I2C-Bus SDA line Write only MBE705 Fig.4 Data shift register/bus buffer S0. In receiver mode the data from the shift register is copied to the read buffer during the acknowledge phase. Further reception of data is inhibited (SCL held LOW) until the S0 read buffer is read (see Section 6.8.1.1). In the transmitter mode data is transmitted to the I2C-bus as soon as it is written to the S0 shift register if the serial I/O is enabled (ESO = 1). Remarks: 1. A minimum of 6 clock cycles must elapse between consecutive parallel-bus accesses to the PCF8584 when the I2C-bus controller operates at 8 or 12 MHz. This may be reduced to 3 clock cycles for lower operating frequencies. 2. To start a read operation immediately after a write, it is necessary to read the S0 read buffer in order to invoke reception of the first byte (‘dummy read’ of the address). Immediately after the acknowledgement, this first byte will be transferred from the shift register to the read buffer. The next read will then transfer the correct value of the first byte to the microcontroller bus (see Fig.7). 6.8 Control/status register S1 Register S1 controls I2C-bus operation and provides I2C-bus status information. Register S1 is accessed by a HIGH signal on register select input A0. For more efficient communication between microcontroller/processor and the I2C-bus, register S1 has separate read and write functions for all bit positions (see Fig.3). The write-only section provides register access control and control over I2C-bus signals, while the read-only section provides I2C-bus status information. Table 4 Control/status register S1 CONTROL/STATUS Control(1) Status(2) BITS PIN ESO ES1 ES2 ENI STA STO ACK write only PIN 0(3) STS BER AD0/LRB AAS LAB BB read only Notes 1. For further information see Section 6.8.1. 2. For further information see Section 6.8.2. 3. Logic 1 if not-initialized. 1997 Oct 21 MODE 9 Philips Semiconductors Product specification I2C-bus controller 6.8.1 PCF8584 REGISTER S1 CONTROL SECTION The write-only section of S1 enables access to registers S0, S0', S1, S2 and S3, and controls I2C-bus operation; see Table 4. 6.8.1.1 PIN (Pending Interrupt Not) When the PIN bit is written with a logic 1, all status bits are reset to logic 0. This may serve as a software reset function (see Figs 5 to 9). PIN is the only bit in S1 which may be both read and written to. PIN is mostly used as a status bit for synchronizing serial communication, see Section 6.8.2. 6.8.1.2 ESO (Enable Serial Output) ESO enables or disables the serial I2C-bus I/O. When ESO is LOW, register access for initialization is possible. When ESO is HIGH, I2C-bus communication is enabled; communication with serial shift register S0 is enabled and the S1 bus status bits are made available for reading. Table 5 Register access control; ESO = 0 (serial interface off) and ESO = 1 (serial interface on) INTERNAL REGISTER ADDRESSING 2-WIRE MODE A0 ES1 IACK ES2 FUNCTION ESO = 0; serial interface off (see note 1) 1 0 X 1(2) R/W S1: control 0 0 0 1(2) R/W S0': (own address) 1 1(2) R/W S3: (interrupt vector) 0 1(2) R/W S2: (clock register) W S1: control 0 0 0 1 ESO = 1; serial interface on 1 0 X 1 1 0 X 1 R S1; status 0 0 0 1 R/W S0: (data) 0 0 1 1 R/W S3: (interrupt vector) X 0 X 0 R S3: (interrupt vector ACK cycle)) Notes 1. With ESO = 0, bits ENI, STA, STO and ACK of S1 can be read for test purposes. 2. ‘X’ if ENI = 0. 6.8.1.3 ES1 and ES2 ES1 and ES2 control selection of other registers for initialization and control of normal operation. After these bits are programmed for access to the desired register (shown in Table 5), the register is selected by a logic LOW level on register select pin A0. 6.8.1.4 ENI This bit enables the external interrupt output INT, which is generated when the PIN bit is active (logic 0). This bit must be set to logic 0 before entering the long-distance mode, and remain at logic 0 during operation in long-distance mode. 1997 Oct 21 10 Philips Semiconductors Product specification I2C-bus controller 6.8.1.5 PCF8584 STA and STO These bits control the generation of the I2C-bus START condition and transmission of slave address and R/W bit, generation of repeated START condition, and generation of the STOP condition (see Table 7). Table 6 Register access control; ESO = 1 (serial interface on) and ES1 = 1; long-distance (4-wire) mode; note 1 INTERNAL REGISTER ADDRESSING: LONG-DISTANCE (4-WIRE) MODE A0 ES1 ES2 IACK 1 1 X 1 W S1: control 1 1 X X R S1; status 0 1 X X R/W S0; (data) FUNCTION Note 1. Trying to read from or write to registers other than S0 and S1 (setting ESO = 0) brings the PCF8584 out of the long-distance mode. Table 7 Instruction table for serial bus control STA STO PRESENT MODE FUNCTION 1 0 SLV/REC START 1 0 MST/TRM REPEAT START 0 1 MST/REC; MST/TRM STOP READ; STOP WRITE 1 1 MST DATA CHAINING 0 0 ANY NOP OPERATION transmit START + address, remain MST/TRM if R/W = 0; go to MST/REC if R/W = 1 same as for SLV/REC transmit STOP go to SLV/REC mode; note 1 send STOP, START and address after last master frame without STOP sent; note 2 no operation; note 3 Notes 1. In master receiver mode, the last byte must be terminated with ACK bit HIGH (‘negative acknowledge’). 2. If both STA and STO are set HIGH simultaneously in master mode, a STOP condition followed by a START condition + address will be generated. This allows ‘chaining’ of transmissions without relinquishing bus control. 3. All other STA and STO mode combinations not mentioned in Table 7 are NOPs. 6.8.1.6 ACK This bit must be set normally to a logic 1. This causes the I2C-bus controller to send an acknowledge automatically after each byte (this occurs during the 9th clock pulse). The bit must be reset (to logic 0) when the I2C-bus controller is operating in master/receiver mode and requires no further data to be sent from the slave transmitter. This causes a negative acknowledge on the I2C-bus, which halts further transmission from the slave device. 6.8.2 REGISTER S1 STATUS SECTION The read-only section of S1 enables access to I2C-bus status information; see Table 4. 1997 Oct 21 11 Philips Semiconductors Product specification I2C-bus controller 6.8.2.1 PCF8584 • In receiver mode, PIN is set to logic 0 (active) on completion of each received byte. Subsequently, the SCL line will be held LOW until PIN is set to logic 1. PIN bit ‘Pending Interrupt Not’ (MSB of register S1) is a status flag which is used to synchronize serial communication and is set to logic 0 whenever the PCF8584 requires servicing. The PIN bit is normally read in polled applications to determine when an I2C-bus byte transmission/reception is completed. The PIN bit may also be written, see Section 6.8.1. • In receiver mode, when register S0 is read, PIN is set to logic 1 (inactive). • In slave receiver mode, an I2C-bus STOP condition will set PIN = 0 (active). • PIN = 0 if a bus error (BER) occurs. Each time a serial data transmission is initiated (by setting the STA bit in the same register), the PIN bit will be set to logic 1 automatically (inactive). When acting as transmitter, PIN is also set to logic 1 (inactive) each time S0 is written. In receiver mode, the PIN bit is automatically set to logic 1 (inactive) each time the data register S0 is read. 6.8.2.2 When in slave receiver mode, this flag is asserted when an externally generated STOP condition is detected (used only in slave receiver mode). 6.8.2.3 After transmission or reception of one byte on the I2C-bus (9 clock pulses, including acknowledge), the PIN bit will be automatically reset to logic 0 (active) indicating a complete byte transmission/reception. When the PIN bit is subsequently set to logic 1 (inactive), all status bits will be reset to logic 0. PIN is also set to zero on a BER (bus error) condition. BER Bus error; a misplaced START or STOP condition has been detected. Resets BB (to logic 1; inactive), sets PIN = 0 (active). 6.8.2.4 LRB/AD0 ‘Last Received Bit’ or ‘Address 0 (General Call) bit’. This status bit serves a dual function, and is valid only while PIN = 0: In polled applications, the PIN bit is tested to determine when a serial transmission/reception has been completed. When the ENI bit (bit 4 of write-only section of register S1) is also set to logic 1 the hardware interrupt is enabled. In this case, the PIN flag also triggers an external interrupt (active LOW) via the INT output each time PIN is reset to logic 0 (active). 1. LRB holds the value of the last received bit over the I2C-bus while AAS = 0 (not addressed as slave). Normally this will be the value of the slave acknowledgement; thus checking for slave acknowledgement is done via testing of the LRB. 2. AD0; when AAS = 1 (‘Addressed As Slave’ condition), the I2C-bus controller has been addressed as a slave. Under this condition, this bit becomes the ‘AD0’ bit and will be set to logic 1 if the slave address received was the ‘general call’ (00H) address, or logic 0 if it was the I2C-bus controller’s own slave address. When acting as slave transmitter or slave receiver, while PIN = 0, the PCF8584 will suspend I2C-bus transmission by holding the SCL line LOW until the PIN bit is set to logic 1 (inactive). This prevents further data from being transmitted or received until the current data byte in S0 has been read (when acting as slave receiver) or the next data byte is written to S0 (when acting as slave transmitter). 6.8.2.5 PIN bit summary: AAS ‘Addressed As Slave’ bit. Valid only when PIN = 0. When acting as slave receiver, this flag is set when an incoming address over the I2C-bus matches the value in own address register S0' (shifted by one bit, see Section 6.4), or if the I2C-bus ‘General Call’ address (00H) has been received (‘General Call’ is indicated when AD0 status bit is also set to logic 1, see Section 6.8.2.4). • The PIN bit can be used in polled applications to test when a serial transmission has been completed. When the ENI bit is also set, the PIN flag sets the external interrupt via the INT output. • Setting the STA bit (start bit) will set PIN = 1 (inactive). • In transmitter mode, after successful transmission of one byte on the I2C-bus the PIN bit will be automatically reset to logic 0 (active) indicating a complete byte transmission. 6.8.2.6 LAB ‘Lost Arbitration’ Bit. This bit is set when, in multi-master operation, arbitration is lost to another master on the I2C-bus. • In transmitter mode, PIN is set to logic 1 (inactive) each time register S0 is written. 1997 Oct 21 STS 12 Philips Semiconductors Product specification I2C-bus controller 6.8.2.7 PCF8584 BB 6.11.1 DELETED FUNCTIONS ‘Bus Busy’ bit. This is a read-only flag indicating when the I2C-bus is in use. A zero indicates that the bus is busy, and access is not possible. This bit is set/reset (logic 1/logic 0) by STOP/START conditions. The following functions are not available in the PCF8584: 6.9 • The non-acknowledge mode (ACK flag) • Always selected (ALS flag) • Access to the bit counter (BC0 to BC2) • Full SCL frequency selection (2 bits instead of 5 bits) Multi-master operation • Asymmetrical clock (ASC flag). To avoid conflict between data and repeated START and STOP operations, multi-master systems have some limitations: 6.11.2 • When powering up multiple PCF8584s in multi-master systems, the possibility exists that one node may power up slightly after another node has already begun an I2C-bus transmission; the Bus Busy condition will thus not have been detected. To avoid this condition, a delay should be introduced in the initialization sequence of each PCF8584 equal to the longest I2C-bus transmission, see flowchart ‘PCF8584 initialization’ (Fig.5). 6.10 The following functions either replace the deleted functions or are completely new: • Chip clock prescaler • Assert acknowledge bit (ACK flag) • Register selection bits (ES1 and ES2 flags) • Additional status flags (BER, ‘bus error’) • Automatic interface control between 80XX and 68000-type microcontrollers • Programmable interrupt vector Reset • Strobe generator A LOW level pulse on the RESET (CLK must run) input forces the I2C-bus controller into a well-defined state. All flags in S1 are reset to logic 0, except the PIN flag and the BB flag, which are set to logic 1. S0' and S3 are set to 00H. • Bus monitor function • Long-distance mode [non-I2C-bus mode (4-wire); only for communication between parallel-bus processors using the PCF8584 at each interface point]. The RESET pin is also used for the STROBE output signal. Both functions are separated on-chip by a digital filter. The reset input signal has to be sufficiently long (minimum 30 clock cycles) to pass through the filter. The STROBE output signal is sufficiently short (8 clock cycles) to be blocked by the filter. For more detailed information on the strobe function see Section 6.12. 6.11 6.12 6.12.1 Special function modes STROBE When the I2C-bus controller receives its own address (or the ‘00H’ general call address) followed immediately by a STOP condition (i.e. no further data transmitted after the address), a strobe output signal is generated at the RESET/STROBE pin (pin 19). The STROBE signal consists of a monostable output pulse (active LOW), 8 clock cycles long (see Fig.9). It is generated after the STOP condition is received, preceded by the correct slave address. This output can be used as a bus access controller for multi-master parallel-bus systems. Comparison to the MAB8400 I2C-bus interface The structure of the PCF8584 is similar to that of the MAB8400 series of microcontrollers, but with a modified control structure. Access to all I2C-bus control and status registers is done via the parallel-bus port in conjunction with register select input A0, and control bits ESO, ES1 and ES2. 1997 Oct 21 ADDED FUNCTIONS 13 Philips Semiconductors Product specification I2C-bus controller 6.12.2 PCF8584 • The controller is always selected. LONG-DISTANCE MODE • The controller is always in the slave receiver mode. The long-distance mode provides the possibility of longer-distance serial communication between parallel processors via two I2C-bus controllers. This mode is selected by setting ES1 to logic 1 while the serial interface is enabled (ESO = 1). • The controller never generates an acknowledge. • The controller never generates an interrupt request. • A pending interrupt condition does not force SCL LOW. • BB is set to logic 0 after detection of a START condition, and reset to logic 1 after a STOP condition. In this mode the I2C-bus protocol is transmitted over 4 unidirectional lines, SDA OUT, SCL IN, SDA IN and SCL IN (pins 2, 3, 4 and 5). These communication lines should be connected to line drivers/receivers (example: RS422) for long-distance applications. Hardware characteristics for long-distance transmission are then given by the chosen standard. Control of data transmission is the same as in normal I2C-bus mode. After reading or writing data to shift register S0, long-distance mode must be initialized by setting ESO and ES1 to logic 1. Because the interrupt output INT is not available in this operating mode, synchronization of data transmission/reception must be polled via the PIN bit. • Received data is automatically transferred to the read buffer. • Bus traffic is monitored by the PIN bit, which is reset to logic 0 after the acknowledge bit of an incoming byte has been received, and is set to logic 1 as soon as the first bit of the next incoming byte is detected. Reading the data buffer S0 sets the PIN bit to logic 1. Data in the read buffer is valid from PIN = 0 and during the next 8 clock pulses (until next acknowledge). • AAS is set to logic 1 at every START condition, and reset at every 9th clock pulse. Remarks: Before entering the long-distance mode, ENI must be set to logic 0. 7 7.1 When powering up an PCF8584-node in long-distance mode, the PCF8584 must be isolated from the 4-wire bus via 3-state line drivers/receivers until the PCF8584 is properly initialized for long-distance mode. Failure to implement this precaution will result in system malfunction. 6.12.3 Initialization The flowchart of Fig.5 gives an example of a proper initialization sequence of the PCF8584. 7.2 Implementation The flowcharts (Figs 6 to 9) illustrate proper programming sequences for implementing master transmitter, master receive, and master transmitter, repeated start and master receiver modes in polled applications. MONITOR MODE When the 7-bit own address register S0' is loaded with all zeros, the I2C-bus controller acts as a passive I2C monitor. The main features of the monitor mode are: 1997 Oct 21 SOFTWARE FLOWCHART EXAMPLES 14 Philips Semiconductors Product specification I2C-bus controller PCF8584 handbook, full pagewidth START power-on address line A0 A0 = HIGH enables data transfer to/from register S1 A0 = LOW Access to all other registers defined by the bit pattern in register S1 reset minimum 30 clock cycles PCF8584 resets to slave receiver mode A0 = HIGH Loads byte 80H into register S1' i.e. next byte will be loaded into register S0' (own address register); serial interface off. send byte 80H parallel bus interface determined by PCF8584 (80XX/68XXX) A0 = LOW Loads byte 55H into register S0'; effective own address becomes AAH. send byte 55H A0 = HIGH Loads byte A0H into register S1, i.e. next byte will be loaded into the clock control register S2. send byte A0H A0 = LOW Loads byte 1CH into register S2; system clock is 12 MHz; SCL = 90 kHz. send byte 1CH A0 = HIGH Loads byte C1H into register S1; register enable serial interface, set I2C-bus into idle mode; SDA and SCL are HIGH. The next write or read operation will be to/from data transfer register S0 if A0 = LOW. send byte C1H delay: wait a time equal to the longest I2C message to synchronize BB-bit. (multimaster systems only On power-on, if an PCF8584 node is powered-up slightly after another node has already begun an I2C-bus transmission, the bus busy condition will not have been detected. Thus, introducing this delay will insure that this condition will not occur. initialization of PCF8584 completed END MBE714 Fig.5 PCF8584 initialization sequence. 1997 Oct 21 15 Philips Semiconductors Product specification I2C-bus controller PCF8584 START handbook, full pagewidth A0 = HIGH read byte from S1 register yes is bus busy? (BB = 0?) no A0 = LOW send byte 'slave address' A0 = HIGH send C5H to control register S1 PCF8584 remains in master transmitter mode if R/W bit of 'slave address' = 0 Load 'slave address' into S0 register: 'slave address' = value of slave address (7-bits + R/W = 0). After reset, default = '0' Load C5H into S1. 'C5H' = PCF8584 generates the 'START' condition and clocks out the slave address and the clock pulse for slave acknowledgement. Next byte(s) sent to the S0 register will be immediately transferred over the I2C-bus. n = 0 (data byte counter); m = number of data bytes to be transferred A0 = HIGH read byte from S1 register no Poll for transmission finished. PIN bit = 0? yes slave acknowledged? (LRB = 0?) yes transmission completed n=m yes A0 = HIGH no send byte C3H n=n+1 A0 = LOW send byte 'data' Load 'data' into bus buffer register S0; data is transmitted. END Fig.6 PCF8584 master transmitter mode. 1997 Oct 21 16 Load C3 into the S1 control register: PCF8584 generates 'STOP' condition. PCF8584 goes into slave receiver mode MBE715 Philips Semiconductors Product specification I2C-bus controller handbook, full pagewidth PCF8584 START A0 = LOW Load 'Slave Address' into S0 register: 'Slave Address' = 7 bits + R/W = 1. send byte 'slave address' to S0 A0 = HIGH read byte from S1 status register yes is bus busy? (BB = 0?) no Is the I2C-bus busy? A0 = HIGH send byte C5H to S1 control register n = 0 (data byte counter) m = number of data bytes to be read PCF8584 generates 'START' condition, sends out slave address + RD to I2C-bus and generates 9th clock pulse for slave ACK. Set-up software counters. A0 = HIGH read byte from S1 status register A0 = HIGH send byte 40H to control register S1 Set ACK bit S1 to 0 in preparation for negative acknowledgement. A0 = LOW read data byte from S0 register(1) no PIN = 0? A0 = HIGH read byte from S1 status register yes slave ACK? (LRB = 0?) n=n+1 yes no no This command simultaneously receives the final data byte from the I2C-bus and loads it into register S0. Neg. ACK is also sent. PIN = 0? (an error has occured) yes A0 = HIGH send byte C3H to S1 n = m − 1? A0 = LOW read final data byte from S0 register A0 = LOW read data byte from S0 register(1) END PCF8584 generates 'STOP' condition. PCF8584 goes into slave receiver mode. This command transfers the final data byte from the data buffer to accumulator. Because the STOP condition was previously executed, no I2C-bus activity takes place. MGL009 (1) The first read of the S0 register is a ‘dummy read’ of the slave address which should be discarded. The first read of the S0 register simultaneously reads the current value of S0 and then transfers the first valid data byte from the I2C-bus to S0. Fig.7 PCF8584 master receiver mode. 1997 Oct 21 17 Philips Semiconductors Product specification I2C-bus controller ndbook, full pagewidth PCF8584 START PCF8584 configured as master transmitter I2C-bus write routine (master transmitter mode excluding final STOP) A0 = HIGH send byte 45H A0 = LOW send byte 'slave address' PCF8584 configured as master receiver Load 45H into the S1 register; PCF8584 generates the repeated 'START condition' only. The current contents of register S0 is NOT clocked out onto the I2C-bus. The next byte sent to register S0 should be the 'slave address' + read bit. Load 'slave address' into the S0 register. Once loaded, it is automatically clocked out over the I2C-bus. 'Slave address' = slave address (7 bits) + R/W bit set '1'. I2C-bus read routine (master receiver mode) END MBE712 Fig.8 Master transmitter followed by repeated START and becoming master receiver. 1997 Oct 21 18 Philips Semiconductors Product specification I2C-bus controller PCF8584 handbook, full pagewidth START A0 = HIGH read byte from S1 register no Check whether 'addressed as slave' addressed as slave (AAS = 1?) yes Check that 'own address' has arrived correctly read byte from S1 register no PIN bit = 0? yes Read incoming address to determine if the R/W bit is 0 or 1 This will differentiate between slave receiver or slave transmitter modes. A0 = LOW read byte from S0 register R/W = 1 SLAVE TRANSMITTER MODE read or write? (LSB = 1 or 0?) R/W = 0 SLAVE RECEIVER MODE A0 = HIGH no read byte from S1 register read byte from S1 register PIN bit = 0? PIN bit = 0? yes yes yes negative ACK received? (LRB = 1?) STOP detected? (STS = 1?) A0 = LOW no read data from S0 register write last data byte to S0 register read last data byte from S0 register PIN deactivated (set to '1') PCF8584 goes into slave receiver mode END RX Fig.9 Slave receiver/slave transmitter modes. 1997 Oct 21 19 yes no write data to S0 register END TX no MBE713 Philips Semiconductors Product specification I2C-bus controller 8 PCF8584 I2C-BUS TIMING DIAGRAMS The diagrams (Figs 10 to 13) illustrate typical timing diagrams for the PCF8584 in master/slave functions. For detailed description of the I2C-bus protocol, please refer to “The I2C-bus and how to use it” ; Philips document ordering number 9398 393 40011. handbook, SDA full pagewidth SCL INT 7-bit address (76H) interrupt first-byte (E4H) R/W = 0 ACK START condition interrupt interrupt nbyte ACK ACK STOP condition MBE709 from slave receiver Master PCF8584 writes data to slave transmitter. Fig.10 Bus timing diagram; master transmitter mode. handbook, SDA full pagewidth SCL INT 7-bit address (76H) interrupt first-byte (discard) interrupt nbyte R/W = 1 START condition ACK ACK no ACK STOP condition 'DUMMY READ' must be executed here from master receiver from slave Master PCF8584 reads data from slave transmitter. Fig.11 Bus timing diagram; master receiver mode. 1997 Oct 21 20 MBE710 Philips Semiconductors Product specification I2C-bus controller PCF8584 handbook, SDA full pagewidth SCL INT 7-bit address (0CH) interrupt first-byte: 1FH interrupt nbyte interrupt R/W = 1 START condition ACK ACK no ACK STOP condition from master receiver from slave PCF8584 MBE711 External master receiver reads data from PCF8584. Fig.12 Bus timing diagram; slave transmitter mode. handbook, SDA full pagewidth SCL INT 7-bit address (62H) interrupt first-byte (CCH) interrupt interrupt nbyte R/W = 0 START condition ACK ACK STOP condition MBE708 from slave PCF8584 Slave PCF8584 is written to by external master transmitter. Fig.13 Bus timing diagram; slave receiver mode. 1997 Oct 21 ACK interrupt (after STOP) 21 Philips Semiconductors Product specification I2C-bus controller PCF8584 9 LIMITING VALUES In accordance with the Absolute Maximum Rating System (IEC 134). SYMBOL PARAMETER MIN. MAX. UNIT VDD supply voltage −0.3 +7.0 V VI voltage range (any input) −0.8 VDD + 0.5 V II DC input current (any input) −10 +10 mA IO DC output current (any output) −10 +10 mA Ptot total power dissipation − 300 mW PO power dissipation per output − 50 mW Tamb operating ambient temperature −40 +85 °C Tstg storage temperature −65 +150 °C 10 HANDLING Inputs and outputs are protected against electrostatic discharge in normal handling. However, to be totally safe, it is good practice to take normal precautions appropriate to handling MOS devices (see “Handling MOS Devices” ). 1997 Oct 21 22 Philips Semiconductors Product specification I2C-bus controller PCF8584 11 DC CHARACTERISTICS VDD = 5 V ±10%; Tamb = −40 to +85 °C; unless otherwise specified. SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT Supply VDD supply voltage IDD supply current 4.5 5.0 5.5 V standby; note 1 − − 2.5 µA operating; notes 1 and 2 − − 1.5 mA Inputs CLK, IACK, A0, CS, WR, RD, RESET AND D0 to D7 VIL LOW level input voltage note 3 0 − 0.8 V VIH HIGH level input voltage note 3 2.0 − VDD V SDA AND SCL VIL LOW level input voltage note 4 0 − 0.3VDD V VIH HIGH level input voltage note 4 0.7VDD − VDD V Ri resistance to VDD Tamb = 25 °C; note 5 25 − 100 kΩ IOH HIGH level output current VOH = 2.4 V; note 6 and 7 −2.4 − − mA IOL LOW level output current VOL = 0.4 V; note 6 3.0 − − mA IOL leakage current note 8 −1 − +1 µA Outputs Notes 1. Test conditions: 22 kΩ pull-up resistors on D0 to D7; 10 kΩ pull-up resistors on SDA, SCL, RD; RESET connected to VSS; remaining pins open-circuit. 2. CLK waveform of 12 MHz with 50% duty factor. 3. CLK, IACK, A0, CS, WR, RD, RESET and D0 to D7 are TTL level inputs. 4. SDA and SCL are CMOS level inputs. 5. CLK, IACK, A0, CS and WR. 6. D0 to D7. 7. DTACK, STROBE. 8. D0 to D7 3-state, SDA, SCL, INT, RD, RESET. 1997 Oct 21 23 Philips Semiconductors Product specification I2C-bus controller PCF8584 12 I2C-BUS TIMING SPECIFICATIONS All the timing limits are valid within the operating supply voltage and ambient temperature range; VDD = 5 V ±10%; Tamb = −40 to +85 °C; and refer to VIL and VIH with an input voltage of VSS to VDD. SYMBOL PARAMETER MIN. TYP. MAX. UNIT fSCL SCL clock frequency − − 100 kHz tSW tolerable spike width on bus − − 100 ns tBUF bus free time 4.7 − − µs tSU;STA START condition set-up time 4.7 − − µs tHD;STA START condition hold time 4.0 − − µs tLOW SCL LOW time 4.7 − − µs tHIGH SCL HIGH time 4.0 − − µs tr SCL and SDA rise time − − 1.0 µs tf SCL and SDA fall time − − 0.3 µs tSU;DAT data set-up time 250 − − ns tHD;DAT data hold time 0 − − ns tVD;DAT SCL LOW to data out valid − − 3.4 µs tSU;STO STOP condition set-up time 4.0 − − µs 13 PARALLEL INTERFACE TIMING All the timing limits are valid within the operating supply voltage and ambient temperature range: VDD = 5 V ±10%; Tamb = −40 to +85 °C; and refer to VIL and VIH with an input voltage of VSS to VDD. CL = 100 pF; RL = 1.5 kΩ (connected to VDD) for open-drain and high-impedance outputs, where applicable (for measurement purposes only). SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT tr clock rise time see Fig.14 − − 6 ns tf clock fall time see Fig.14 − − 6 ns tCLK input clock period (50% ±5% duty factor) see Fig.14 83 − 333 ns tCLRL CS set-up to RD LOW see Fig.16 and note 1 20 − − ns tCLWL CS set-up to WR LOW see Fig.15 and note 1 20 − − ns tRHCH CS hold from RD HIGH see Fig.16 0 − − ns tWHCH CS hold from WR HIGH see Fig.15 0 − − ns tAVWL A0 set-up to WR LOW see Fig.15 10 − − ns tAVRL A0 set-up to RD LOW see Fig.16 10 − − ns tWHAI A0 hold from WR HIGH see Fig.15 20 − − ns tRHAI A0 hold from RD HIGH see Fig.16 10 − − ns tWLWH WR pulse width see Fig.15 230 − 1000 ns tRLRH RD pulse width see Fig.16 230 − 1000 ns tDVWH data set-up before WR HIGH see Fig.15 150 − − ns tRLDV data valid after RD LOW see Fig.16 − 160 180 ns tWHDI data hold after WR HIGH see Fig.15 20 − − ns tRHDF data bus floating after RD HIGH see Fig.16 − − 150 ns 1997 Oct 21 24 Philips Semiconductors Product specification I2C-bus controller SYMBOL PARAMETER PCF8584 CONDITIONS MIN. TYP. MAX. UNIT tAVCL A0 set-up to CS LOW see Figs 17 and 18 10 − − ns tWLCL R/WR set-up to CS LOW see Fig.17 10 − − ns tRHCL R/WR set-up to CS LOW see Fig.18 10 − − ns tCLDV data valid after CS LOW see Fig.18 and note 2 − 160 180 ns tCLDL DTACK LOW after CS LOW see Figs 17 and 18 − 2tCLK + 75 3tCLK + 150 ns tCHAI A0 hold from CS HIGH see Fig.18 0 − − ns tCHRL R/WR hold from CS HIGH see Fig.18 0 − − ns tCHWH R/WR hold from CS HIGH see Fig.17 0 − − ns tCHDF data bus float after CS HIGH see Fig.18 − − 150 ns tCHDE DTACK HIGH from CS HIGH see Figs 17 and 18 − 100 120 ns tCHDI data hold after CS HIGH see Fig.17 0 − − ns tDVCL data set-up to CS LOW see Fig.17 0 − − ns tALIE INT HIGH from IACK LOW see Figs 19 and 20 − 130 180 ns tALDV data valid after IACK LOW see Figs 19 and 20 − 200 250 ns tALAE IACK pulse width see Fig.20 230 − − ns tAHDI data hold after IACK HIGH see Fig.20 − − 30 ns tALDL DTACK LOW from IACK LOW see Fig.20 − 2tCLK + 75 3tCLK + 150 ns tAHDE DTACK HIGH from IACK HIGH see Fig.20 − 120 140 ns tW4 RESET pulse width see Fig.21 30tCLK − − ns tW5 STROBE pulse width see Fig.22 8tCLK 8tCLK + 90 − ns tCLCL CS LOW see Figs 17 and 18 − tCLDL + tCHDE − ns Notes 1. A minimum of 6 clock cycles must elapse between consecutive parallel-bus accesses when the I2C-bus controller operates at 8 or 12 MHz. This may be reduced to 3 clock cycles for lower operating frequencies. 2. Not for S1. 1997 Oct 21 25 Philips Semiconductors Product specification I2C-bus controller PCF8584 t CLK handbook, full pagewidth 35.5 ns min 35.5 ns min CLK tr 6 ns max tf 6 ns max tf MLA013 - 1 Fig.14 Clock input timing. CS t CLWL t WHCH A0 t AVWL t WHAI WR t WLWH DATA VALID D0 to D7 t DVWH MLA014 - 1 Fig.15 Bus timing (80XX mode); write cycle. 1997 Oct 21 26 t WHDI Philips Semiconductors Product specification I2C-bus controller PCF8584 handbook, full pagewidth CS t CLRL t RHCH A0 t AVRL t RHAI RD t RLRH DATA VALID D0 to D7 MLA015 - 1 t RLDV t RHDF Fig.16 Bus timing (80XX mode); read cycle. handbook, full pagewidth A0 t CHAI t AVCL R/W t WLCL t CLCL t CHWH CS D0 to D7 DATA VALID t DVCL t CHDI DTACK MLA017 - 1 t CLDL t CHDE Fig.17 Bus timing (68000 mode); write cycle. 1997 Oct 21 27 Philips Semiconductors Product specification I2C-bus controller PCF8584 A0 t CHAL t AVCL R/W t RHCL t CLCL t CHRL CS D0 to D7 DATA VALID t CLDV t CHDF DTACK t CLDL MLA016 - 1 t CHDE Fig.18 Bus timing (68000 mode); read cycle. t ALIE INT t ALAE IACK t ALDV t AHDI D0 to D7 DATA VALID MLA018 - 1 Fig.19 Interrupt timing (80XX mode). 1997 Oct 21 28 Philips Semiconductors Product specification I2C-bus controller PCF8584 t ALIE handbook, full pagewidth INT t ALAE IACK t ALDV t AHDI D0 to D7 DATA VALID t ALDL t AHDE DTACK MLA019 - 1 Fig.20 Interrupt timing (68000 mode). CLK RESET t W4 Fig.21 Reset timing. 1997 Oct 21 29 MLA020 - 1 Philips Semiconductors Product specification I2C-bus controller PCF8584 CLK STROBE t W5 Fig.22 Strobe timing. 1997 Oct 21 30 MLA021 - 1 Philips Semiconductors Product specification I2C-bus controller PCF8584 14 APPLICATION INFORMATION ADDRESS BUS A0 DECODER CS ALE SCL 8048/8051 DATA PCF8584 RD SDA WR INT MBE704 Fig.23 Application diagram using the 8048/8051. 1997 Oct 21 31 Philips Semiconductors Product specification I2C-bus controller PCF8584 AS UDS DECODER LDS CS ADDRESS A1 A1, A2, A3 68000 FCX IPX SCL IACK INTERRUPT HANDLER PCF8584 INT SDA R/W DTACK DATA MBE702 Fig.24 Application diagram using the 68000. 1997 Oct 21 32 Philips Semiconductors Product specification I2C-bus controller PCF8584 ADDRESS BUS A0 DECODER CS ALE SCL IOR 8088 PCF8584 IOW SDA DATA INTR INT IACK MBE703 Fig.25 Application diagram using the 8088. 1997 Oct 21 33 Philips Semiconductors Product specification I2C-bus controller PCF8584 handbook, full pagewidth Substrate CLK 1 20 VDD SDA or SDA OUT 2 19 RESET/STROBE SCL or SCL IN 3 18 WR (R/W) IACK or SDA IN 4 17 CS INT or SCL OUT 5 16 RD (DTACK) A0 6 15 DB7 DB0 7 14 DB6 DB1 8 13 DB5 DB2 9 12 DB4 VSS 10 11 DB3 (1) MBE701 Maximum forward current: 5 mA; maximum reverse voltage: 5 V. Fig.26 PCF8584 diode protection. 14.1 Application notes Additional application notes are available from Philips Semiconductors: 1. AN95068: “C Routines for the PCF8584”. 2. AN96040: “Using the PCF8584 with non-specified timings and other frequently asked questions”. 3. AN90001: “Interfacing PCF8584 I2C-bus controller to 80(C)51 family of microcontrollers”. 1997 Oct 21 34 Philips Semiconductors Product specification I2C-bus controller PCF8584 15 PACKAGE OUTLINES DIP20: plastic dual in-line package; 20 leads (300 mil) SOT146-1 ME seating plane D A2 A A1 L c e Z b1 w M (e 1) b MH 11 20 pin 1 index E 1 10 0 5 10 mm scale DIMENSIONS (inch dimensions are derived from the original mm dimensions) UNIT A max. A1 min. A2 max. b b1 c mm 4.2 0.51 3.2 1.73 1.30 0.53 0.38 0.36 0.23 26.92 26.54 inches 0.17 0.020 0.13 0.068 0.051 0.021 0.015 0.014 0.009 1.060 1.045 D e e1 L ME MH w Z (1) max. 6.40 6.22 2.54 7.62 3.60 3.05 8.25 7.80 10.0 8.3 0.254 2.0 0.25 0.24 0.10 0.30 0.14 0.12 0.32 0.31 0.39 0.33 0.01 0.078 (1) E (1) Note 1. Plastic or metal protrusions of 0.25 mm maximum per side are not included. OUTLINE VERSION SOT146-1 1997 Oct 21 REFERENCES IEC JEDEC EIAJ SC603 35 EUROPEAN PROJECTION ISSUE DATE 92-11-17 95-05-24 Philips Semiconductors Product specification I2C-bus controller PCF8584 SO20: plastic small outline package; 20 leads; body width 7.5 mm SOT163-1 D E A X c HE y v M A Z 11 20 Q A2 A (A 3) A1 pin 1 index θ Lp L 1 10 e bp detail X w M 0 5 10 mm scale DIMENSIONS (inch dimensions are derived from the original mm dimensions) UNIT A max. A1 A2 A3 bp c D (1) E (1) e HE L Lp Q v w y mm 2.65 0.30 0.10 2.45 2.25 0.25 0.49 0.36 0.32 0.23 13.0 12.6 7.6 7.4 1.27 10.65 10.00 1.4 1.1 0.4 1.1 1.0 0.25 0.25 0.1 0.9 0.4 inches 0.10 0.012 0.096 0.004 0.089 0.01 0.019 0.013 0.014 0.009 0.51 0.49 0.30 0.29 0.050 0.419 0.043 0.055 0.394 0.016 0.043 0.039 0.01 0.01 0.004 0.035 0.016 Z (1) θ 8o 0o Note 1. Plastic or metal protrusions of 0.15 mm maximum per side are not included. REFERENCES OUTLINE VERSION IEC JEDEC SOT163-1 075E04 MS-013AC 1997 Oct 21 EIAJ EUROPEAN PROJECTION ISSUE DATE 95-01-24 97-05-22 36 Philips Semiconductors Product specification I2C-bus controller PCF8584 Several techniques exist for reflowing; for example, thermal conduction by heated belt. Dwell times vary between 50 and 300 seconds depending on heating method. Typical reflow temperatures range from 215 to 250 °C. 16 SOLDERING 16.1 Introduction There is no soldering method that is ideal for all IC packages. Wave soldering is often preferred when through-hole and surface mounted components are mixed on one printed-circuit board. However, wave soldering is not always suitable for surface mounted ICs, or for printed-circuits with high population densities. In these situations reflow soldering is often used. Preheating is necessary to dry the paste and evaporate the binding agent. Preheating duration: 45 minutes at 45 °C. 16.3.2 This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in our “IC Package Databook” (order code 9398 652 90011). 16.2 16.2.1 Wave soldering techniques can be used for all SO packages if the following conditions are observed: • A double-wave (a turbulent wave with high upward pressure followed by a smooth laminar wave) soldering technique should be used. DIP SOLDERING BY DIPPING OR BY WAVE • The longitudinal axis of the package footprint must be parallel to the solder flow. The maximum permissible temperature of the solder is 260 °C; solder at this temperature must not be in contact with the joint for more than 5 seconds. The total contact time of successive solder waves must not exceed 5 seconds. • The package footprint must incorporate solder thieves at the downstream end. During placement and before soldering, the package must be fixed with a droplet of adhesive. The adhesive can be applied by screen printing, pin transfer or syringe dispensing. The package can be soldered after the adhesive is cured. The device may be mounted up to the seating plane, but the temperature of the plastic body must not exceed the specified maximum storage temperature (Tstg max). If the printed-circuit board has been pre-heated, forced cooling may be necessary immediately after soldering to keep the temperature within the permissible limit. 16.2.2 Maximum permissible solder temperature is 260 °C, and maximum duration of package immersion in solder is 10 seconds, if cooled to less than 150 °C within 6 seconds. Typical dwell time is 4 seconds at 250 °C. REPAIRING SOLDERED JOINTS A mildly-activated flux will eliminate the need for removal of corrosive residues in most applications. Apply a low voltage soldering iron (less than 24 V) to the lead(s) of the package, below the seating plane or not more than 2 mm above it. If the temperature of the soldering iron bit is less than 300 °C it may remain in contact for up to 10 seconds. If the bit temperature is between 300 and 400 °C, contact may be up to 5 seconds. 16.3 16.3.1 16.3.3 REPAIRING SOLDERED JOINTS Fix the component by first soldering two diagonallyopposite end leads. Use only a low voltage soldering iron (less than 24 V) applied to the flat part of the lead. Contact time must be limited to 10 seconds at up to 300 °C. When using a dedicated tool, all other leads can be soldered in one operation within 2 to 5 seconds between 270 and 320 °C. SO REFLOW SOLDERING Reflow soldering techniques are suitable for all SO packages. Reflow soldering requires solder paste (a suspension of fine solder particles, flux and binding agent) to be applied to the printed-circuit board by screen printing, stencilling or pressure-syringe dispensing before package placement. 1997 Oct 21 WAVE SOLDERING 37 Philips Semiconductors Product specification I2C-bus controller PCF8584 17 DEFINITIONS Data sheet status Objective specification This data sheet contains target or goal specifications for product development. Preliminary specification This data sheet contains preliminary data; supplementary data may be published later. Product specification This data sheet contains final product specifications. Limiting values Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information Where application information is given, it is advisory and does not form part of the specification. 18 LIFE SUPPORT APPLICATIONS These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such improper use or sale. 19 PURCHASE OF PHILIPS I2C COMPONENTS Purchase of Philips I2C components conveys a license under the Philips’ I2C patent to use the components in the I2C system provided the system conforms to the I2C specification defined by Philips. This specification can be ordered using the code 9398 393 40011. 1997 Oct 21 38 Philips Semiconductors Product specification I2C-bus controller PCF8584 NOTES 1997 Oct 21 39 Philips Semiconductors – a worldwide company Argentina: see South America Australia: 34 Waterloo Road, NORTH RYDE, NSW 2113, Tel. +61 2 9805 4455, Fax. +61 2 9805 4466 Austria: Computerstr. 6, A-1101 WIEN, P.O. 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No. 5, 80640 GÜLTEPE/ISTANBUL, Tel. +90 212 279 2770, Fax. +90 212 282 6707 Ukraine: PHILIPS UKRAINE, 4 Patrice Lumumba str., Building B, Floor 7, 252042 KIEV, Tel. +380 44 264 2776, Fax. +380 44 268 0461 United Kingdom: Philips Semiconductors Ltd., 276 Bath Road, Hayes, MIDDLESEX UB3 5BX, Tel. +44 181 730 5000, Fax. +44 181 754 8421 United States: 811 East Arques Avenue, SUNNYVALE, CA 94088-3409, Tel. +1 800 234 7381 Uruguay: see South America Vietnam: see Singapore Yugoslavia: PHILIPS, Trg N. Pasica 5/v, 11000 BEOGRAD, Tel. +381 11 625 344, Fax.+381 11 635 777 For all other countries apply to: Philips Semiconductors, Marketing & Sales Communications, Building BE-p, P.O. Box 218, 5600 MD EINDHOVEN, The Netherlands, Fax. +31 40 27 24825 Internet: http://www.semiconductors.philips.com © Philips Electronics N.V. 1997 SCA55 All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights. Printed in The Netherlands 417067/00/04/pp40 Date of release: 1997 Oct 21 Document order number: 9397 750 02932