i2s-bus i2s总线规范 specification

Philips Semiconductors I2S bus specification 1February 1986 Revised: June 5, 1996 1.0 INTRODUCTION Many digital audio systems are being introduced into the consumer audio market, including compact disc, digital audio tape, digital sound processors, and digital TV-sound. The digital audio signals in these systems are being processed by a number of (V)LSI ICs, such as: • A/D and D/A converters; • digital signal processors; • error correction for compact disc and digital recording; • digital filters; • digital input/output interfaces. Standardized communication structures are vital for both the equipment and the IC manufacturer, because they increase system flexibility. To this end, we have developed the inter-IC sound (I2S) bus – a serial link especially for digital audio. 2.0 BASIC SERIAL BUS REQUIREMENTS The bus has only to handle audio data, while the other signals, such as sub-coding and control, are transferred separately. To minimize the number of pins required and to keep wiring simple, a 3-line serial bus is used consisting of a line for two time-multiplexed data channels, a word select line and a clock line. Since the transmitter and receiver have the same clock signal for data transmission, the transmitter as the master, has to generate the bit clock, word-select signal and data. In complex systems however, there may be several transmitters and receivers, which makes it difficult to define the master. In such systems, there is usually a system master controlling digital audio data-flow between the various ICs. Transmitters then, have to generate data under the control of an external clock, and so act as a slave. Figure 1 illustrates some simple system configurations and the basic interface timing. Note that the system master can be combined with a transmitter or receiver, and it may be enabled or disabled under software control or by pin programming. TRANSMITTER clock SCK word select WS data SD RECEIVER TRANSMITTER = MASTER TRANSMITTER SCK WS SD RECEIVER RECEIVER = MASTER TRANSMITTER SCK WS SD RECEIVER CONTROLLER = MASTER CONTROLLER SCK WS SD WORD n–1 RIGHT CHANNEL WORD n+1 RIGHT CHANNEL WORD n LEFT CHANNEL LSB MSBMSB SN00119 Figure 1. Simple System Configurations and Basic Interface Timing Philips Semiconductors I2S bus specification February 1986 2 3.0 THE I2S BUS As shown in Figure 1, the bus has three lines: • continuous serial clock (SCK); • word select (WS); • serial data (SD); and the device generating SCK and WS is the master. 3.1 Serial Data Serial data is transmitted in two’s complement with the MSB first. The MSB is transmitted first because the transmitter and receiver may have different word lengths. It isn’t necessary for the transmitter to know how many bits the receiver can handle, nor does the receiver need to know how many bits are being transmitted. When the system word length is greater than the transmitter word length, the word is truncated (least significant data bits are set to ‘0’) for data transmission. If the receiver is sent more bits than its word length, the bits after the LSB are ignored. On the other hand, if the receiver is sent fewer bits than its word length, the missing bits are set to zero internally. And so, the MSB has a fixed position, whereas the position of the LSB depends on the word length. The transmitter always sends the MSB of the next word one clock period after the WS changes. Serial data sent by the transmitter may be synchronized with either the trailing (HIGH-to-LOW) or the leading (LOW-to-HIGH) edge of the clock signal. However, the serial data must be latched into the receiver on the leading edge of the serial clock signal, and so there are some restrictions when transmitting data that is synchronized with the leading edge (see Figure 2 and Table 1). 3.2 Word Select The word select line indicates the channel being transmitted: • WS = 0; channel 1 (left); • WS = 1; channel 2 (right). WS may change either on a trailing or leading edge of the serial clock, but it doesn’t need to be symmetrical. In the slave, this signal is latched on the leading edge of the clock signal. The WS line changes one clock period before the MSB is transmitted. This allows the slave transmitter to derive synchronous timing of the serial data that will be set up for transmission. Furthermore, it enables the receiver to store the previous word and clear the input for the next word (see Figure 1). 4.0 TIMING In the I2S format, any device can act as the system master by providing the necessary clock signals. A slave will usually derive its internal clock signal from an external clock input. This means, taking into account the propagation delays between master clock and the data and/or word-select signals, that the total delay is simply the sum of: • the delay between the external (master) clock and the slave’s internal clock; and • the delay between the internal clock and the data and/or word-select signals. For data and word-select inputs, the external to internal clock delay is of no consequence because it only lengthens the effective set-up time (see Figure 2). The major part of the time margin is to accommodate the difference between the propagation delay of the transmitter, and the time required to set up the receiver. All timing requirements are specified relative to the clock period or to the minimum allowed clock period of a device. This means that higher data rates can be used in the future. SD and WS SCK T tRC* tLC ≥ 0.35T tHC ≥ 0.35T VH = 2.0V VL = 0.8V thtr ≥ 0 tdtr ≤ 0.8T T = clock period Ttr = minimum allowed clock period for transmitter T > Ttr ∗ tRC is only relevant for transmitters in slave mode. SN00120 Figure 2. Timing for I2S Transmitter Philips Semiconductors I2S bus specification February 1986 3 SD and WS SCK T tLC ≥ 0.35T tHC ≥ 0.35 VH = 2.0V VL = 0.8V T = clock period Tr = minimum allowed clock period for transmitter T > Tr tsr ≥ 0.2T thr ≥ 0 SN00121 Figure 3. Timing for I2S Receiver Note that the times given in both Figures 2 and 3 are defined by the transmitter speed. The specification of the receiver has to be able to match the performance of the transmitter Example: Master transmitter with data rate of 2.5MHz (±10%) (all values in ns) MIN TYP MAX CONDITION clock period T 360 400 440 Ttr = 360 clock HIGH tHC 160 min > 0.35T = 140 (at typical data rate) clock LOW tLC 160 min > 0.35T = 140 (at typical data rate) delay tdtr 300 max < 0.80T = 320 (at typical data rate) hold time thtr 100 min > 0 clock rise-time tRC 60 max > 0.15Ttr = 54 (only relevant in slave mode) Example: Slave receiver with data rate of 2.5MHz (±10%) (all values in ns) MIN TYP MAX CONDITION clock period T 360 400 440 Ttr = 360 clock HIGH tHC 110 min < 0.35T = 126 clock LOW tLC 110 min < 0.35T = 126 set-up time tsr 60 min < 0.20T = 72 hold time thtr 0 min < 0 Philips Semiconductors I2S bus specification February 1986 4 Table 1. Timing for I2S transmitters and receivers TRANSMITTER RECEIVER LOWER LIMIT UPPER LIMIT LOWER LIMIT UPPER LIMIT MIN MAX MIN MAX MIN MAX MIN MAX NOTES Clock period T Ttr Tr 1 MASTER MODE: clock generated by transmitter or receiver: HIGH tHC 0.35Ttr 0.35Ttr 2a LOW tLC 0.35Ttr 0.35Ttr 2a SLAVE MODE: clock accepted by transmitter or receiver: HIGH tHC 0.35Ttr 0.35Tr 2b LOW tLC 0.35Ttr 0.35Tr 2b rise-time tRC 0.15Ttr 3 TRANSMITTER: delay tdtr 0.8T 4 hold time thtr 0 3 RECEIVER: set-up time tsr 0.2Tr 5 hold time thr 0 5 All timing values are specified with respect to high and low threshold levels. NOTES: 1. The system clock period T must be greater than Ttr and Tr because both the transmitter and receiver have to be able to handle the data transfer rate. 2a. At all data rates in the master mode, the transmitter or receiver generates a clock signal with a fixed mark/space ratio. For this reason tHC and tLC are specified with respect to T. 2b. In the slave mode, the transmitter and receiver need a clock signal with minimum HIGH and LOW periods so that they can detect the signal. So long as the minimum periods are greater than 0.35Tr, any clock that meets the requirements can be used (see Figure 3). 3. Because the delay (tdtr) and the maximum transmitter speed (defined by Ttr) are related, a fast transmitter driven by a slow clock edge can result in tdtr not exceeding tRC which means thtr becomes zero or negative. Therefore, the transmitter has to guarantee that thtr is greater than or equal to zero, so long as the clock rise-time tRC is not more than tRCmax, where tRCmax is not less than 0.15Ttr. 4. To allow data to be clocked out on a falling edge, the delay is specified with respect to the rising edge of the clock signal and T, always giving the receiver sufficient set-up time. 5. The data set-up and hold time must not be less than the specified receiver set-up and hold time. tRC VH VL VH VL ACTIVE RISING CLOCK EDGE DATA thtr tdtr SN00122 Figure 4. Clock rise-time definition with respect to the voltage levels Philips Semiconductors I2S bus specification February 1986 5 5.0 VOLTAGE LEVEL SPECIFICATION 5.1 Output Levels VL < 0.4V VH > 2.4V both levels able to drive one standard TTL input (IIL = –1.6mA and IIH = 0.04mA). 5.2 Input Levels VIL = 0.8V VIH = 2.0V Note: At present, TTL is considered a standard for logic levels. As other IC (LSI) technologies become popular, other levels will also be supported. 6.0 POSSIBLE HARDWARE CONFIGURATIONS 6.1 Transmitter (see Figure 5) At each WS-level change, a pulse WSP is derived for synchronously parallel-loading the shift register. The output of one of the data latches is then enabled depending on the WS signal. Since the serial data input is zero, all the bits after the LSB will also be zero. 6.2 Receiver (see Figure 6) Following the first WS-level change, WSP will reset the counter on the falling edge of SCK. After decoding the counter value in a “1 out of n” decoder, the MSB latch (B1) is enabled (EN1 = 1), and the first serial data bit (the MSB) is latched into B1 on the rising edge of SCK. As the counter increases by one every clock pulse, subsequent data bits are latched into B2 to Bn. On the next WS-level change, the contents of the n latches are written in parallel, depending on WSD, into either the left or the right data-word latch. After this, latches B2 to Bn are cleared and the counter reset. If there are more than n serial data bits to be latched, the counter is inhibited after Bn (the receiver’s LSB) is filled and subsequent bits are ignored. Note: The counter and decoder can be replaced by an n-bit shift-register (see Figure 7) in which a single ‘1’ is loaded into the MSB position when WSP occurs. On every subsequent clock pulse, this ‘1’ shifts one place, enabling the N latches. This configuration may prove useful if the layout has to be taken into account. SCK WS SD LSB MSBMSB WSP DATA LEFT DATA RIGHT SD MSBLSB D CLK SCK SHIFT REGISTER PL D Q CLK SYNCHRONOUS PARALLEL LOADING WSP WSD D Q CLK Q SCK WS WSD OE OEWSD SN00123 Figure 5. Possible transmitter configuration Philips Semiconductors I2S bus specification February 1986 6 DATA LEFT DATA RIGHT D Q CLK WSP WSD D Q CLK WS COUNTER EN1 EN2 ENn CLK EN R WSP SCK D Q CLK EN B1 MSB EN1 D Q CLK EN B2 EN2 R D Q CLK EN B3 EN3 R D Q CLK EN R D Q CLK EN Bn ENn R LSB SD WSD SCK CLK ENWSD CLK EN SCKWSP SN00124 Figure 6. Possible receiver configuration. The latches and the counter use synchronous set, reset and enable inputs, where set overrules the reset input, and reset overrules the enable input. Philips Semiconductors I2S bus specification February 1986 7 DATA LEFT DATA RIGHT D Q CLK WSP WSD D Q CLK WS WSP SCK D Q CLK EN B1 MSB D Q CLK EN B2 R D Q CLK EN B3 R D Q CLK EN R D Q CLK EN Bn R LSB SD WSD SCK CLK ENWSD CLK EN SCKWSP D Q CLK D Q CLK R D Q CLK R D Q CLK RS SN00125 Figure 7. Possible receiver configuration, using an n-bit shift-register to enable control of data input register.