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ISD5102EYIR

ISD5102EYIR

  • 厂商:

    NUVOTON(新唐)

  • 封装:

    TSSOP28

  • 描述:

    IC VOICE REC/PLAY 1-2MN 28-TSOP

  • 数据手册
  • 价格&库存
ISD5102EYIR 数据手册
ISD5100 ISD ChipCorder® ISD5100 Series Datasheet The information described in this document is the exclusive intellectual property of Nuvoton Technology Corporation and shall not be reproduced without permission from Nuvoton. Nuvoton is providing this document only for reference purposes of Audio Product Line based system design. Nuvoton assumes no responsibility for errors or omissions. All data and specifications are subject to change without notice. For additional information or questions, please contact: Nuvoton Technology Corporation. www.nuvoton.com Jun 28, 2021 Page 1 of 85 Rev1.6 ISD5100 Table of Contents 1. GENERAL DESCRIPTION .................................................................................... 4 2. FEATURES............................................................................................................ 5 3. BLOCK DIAGRAM ................................................................................................. 6 4. PIN CONFIGURATION .......................................................................................... 7 5. PIN DESCRIPTION ............................................................................................... 8 6. FUNCTIONAL DESCRIPTION .............................................................................. 9 6.1. Overview ......................................................................................................... 9 6.1.1 Speech/Voice Quality ................................................................................ 9 6.1.2 Duration..................................................................................................... 9 6.1.3 Flash Technology ...................................................................................... 9 6.1.4 Microcontroller Interface ............................................................................ 9 6.1.5 Programming............................................................................................. 9 6.2. Functional Details .......................................................................................... 10 6.2.1 Internal Registers .................................................................................... 11 6.2.2 Memory Architecture ............................................................................... 11 6.3. Operational Modes Description ..................................................................... 12 6.3.1 I2C Interface ............................................................................................ 12 6.3.2 I2C Control Registers............................................................................... 16 6.3.3 Opcode Summary ................................................................................... 17 6.3.4 Data Bytes............................................................................................... 19 6.3.5 Configuration Register Bytes................................................................... 19 6.3.6 Power-up Sequence ................................................................................ 21 6.3.7 Feed Through Mode ................................................................................ 21 6.3.8 Call Record ............................................................................................. 24 6.3.9 Memo Record .......................................................................................... 25 6.3.10 Memo and Call Playback......................................................................... 26 6.3.11 Message Cueing ..................................................................................... 27 6.4. Analog Mode ................................................................................................. 27 6.4.1 Aux In and Ana In Description ................................................................. 27 6.4.2 ISD5100 Series Analog Structure (left half) Description .......................... 28 6.4.3 ISD5100 Series Aanalog Structure (right half) Description...................... 28 6.4.4 Volume Control Description..................................................................... 30 6.4.5 Speaker and Aux Out Description ........................................................... 31 6.4.6 Ana Out Description ................................................................................ 32 6.4.7 Analog Inputs .......................................................................................... 32 6.5. Digital Mode .................................................................................................. 35 6.5.1 Erasing Digital Data................................................................................. 35 6.5.2 Writing Digital Data.................................................................................. 35 6.5.3 Reading Digital Data ............................................................................... 35 6.5.4 Example Command Sequences .............................................................. 35 6.6. Pin Details ..................................................................................................... 46 Jun 28, 2021 Page 2 of 85 Rev1.6 ISD5100 6.6.1 Digital I/O Pins ........................................................................................ 46 6.6.2 Analog I/O Pins ....................................................................................... 48 6.6.3 Power and Ground Pins .......................................................................... 52 6.6.4 PCB Layout Examples ............................................................................ 53 7. TIMING DIAGRAMS ............................................................................................ 54 7.1 I2C Timing Diagram ....................................................................................... 54 7.2 Playback and Stop Cycle .............................................................................. 56 7.3 Example of Power Up Command (first 12 bits) ............................................. 57 8. ABSOLUTE MAXIMUM RATINGS ...................................................................... 58 9. ELECTRICAL CHARACTERISTICS .................................................................... 60 9.1. General Parameters ...................................................................................... 60 9.2. Timing Parameters ........................................................................................ 61 9.3. Analog Parameters ....................................................................................... 63 9.4. Characteristics of The I2C Serial Interface .................................................... 68 9.5. I2C Protocol ................................................................................................... 70 10. TYPICAL APPLICATION CIRCUIT...................................................................... 72 11. PACKAGE SPECIFICATION ............................................................................... 73 11.1. 28-Lead 300-Mil Plastic Small Outline Integrated Circuit (SOIC) .................. 73 11.2. 28-Lead 600-Mil Plastic Dual Inline Package (PDIP) .................................... 74 11.3. ISD5116 Die Information ............................................................................... 75 11.4. ISD5108 Die Information ............................................................................... 77 11.5. ISD5104 Die Information ............................................................................... 79 11.6. ISD5102 Die Information ............................................................................... 81 12. ORDERING INFORMATION ............................................................................... 83 13. REVISION HISTORY ........................................................................................... 84 Important Notice...................................................................................................... 85 Jun 28, 2021 Page 3 of 85 Rev1.6 ISD5100 1. GENERAL DESCRIPTION The ISD5100 ChipCorder Series provide high quality, fully integrated, single-chip Record/Playback solutions for 1- to 16-minute messaging applications that are ideal for use in cellular phones, automotive communications, GPS/navigation systems and other portable products. The ISD5100 Series products are an enhancement of the ISD5000 architecture, providing: 1) the I2C serial port - address, control and duration selection are accomplished through an I2C interface to minimize pin count (ONLY two control lines required); 2) the capability of storing digital data, in addition to analog data. This feature allows customers to store phone numbers, system configuration parameters and message address locations for message management capability; 3) Various internal circuit blocks can be individually powered-up or -down for power saving. The ISD5100 Series include: • ISD5116 from 8 to 16 minutes • ISD5108 from 4 to 8 minutes • ISD5104 from 2 to 4 minutes • ISD5102 from 1 to 2 minutes Analog functions and audio gating have also been integrated into the ISD5100 Series products to allow easy interface with integrated digital cellular chip sets on the market. Audio paths have been designed to enable full duplex conversation record, voice memo, answering machine (including outgoing message playback) and call screening features. This product enables playback of messages while the phone is in standby, AND both simplex and duplex playback of messages while on a phone call. Additional voice storage features for digital cellular phones include: 1) a personalized outgoing message can be sent to the person by getting caller-ID information from the host chipset, 2) a private call announce while on call can be heard from the host by giving caller-ID on call waiting information from the host chipset. Logic Interface Options of 2.0V and 3.0V are supported by the ISD5100 Series to accommodate portable communication products (2.0- and 3.0-volt required). Like other ChipCorder® products, the ISD5100 Series integrate the sampling clock, anti-aliasing and smoothing filters, and the multi-level storage array on a single-chip. For enhanced voice features, the ISD5100 Series eliminate external circuitry by integrating automatic gain control (AGC), a power amplifier/speaker driver, volume control, summing amplifiers, analog switches, and a car kit interface. Input level adjustable amplifiers are also included, providing a flexible interface for multiple applications. Recordings are stored into on-chip nonvolatile memory cells, providing zero-power message storage. This unique, single-chip solution is made possible through Nuvoton’s patented multilevel storage technology. Voice and audio signals are stored directly into solid-state memory in their natural, uncompressed form, providing superior quality on voice and music reproduction. Jun 28, 2021 Page 4 of 85 Rev1.6 ISD5100 2. FEATURES Fully-Integrated Solution • • • Single-chip voice record/playback solution Dual storage of digital and analog data Durations Device ISD5102 Duration 1 to 2 minutes ISD5104 2 to 4 minutes ISD5108 4 to 8 minutes ISD5116 8 to 16 minutes Low Power Consumption • • • • • Supply Voltage  Commercial Temperature = +2.7V to +3.3V  Industrial Temperature = +2.7V to +3.3V (+2.7V to +3.6V for ISD5108 only) Supports 2.0V and 3.0V interface logic Operating Current:  ICC Play = 15 mA (typical)  ICC Rec = 30 mA (typical)  ICC Feedthrough = 12 mA (typical) Standby Current:  ISB = 1µA (typical) Most stages can be individually powered down to minimize power consumption Enhanced Voice Features • • • • • • • One or two-way conversation record One or two-way message playback Voice memo record and playback Private call screening In-terminal answering machine Personalized outgoing message Private call announce while on call Digital Memory Features • Device ISD5102 ISD5104 ISD5108 ISD5116 Storage Up to 512Kb Up to 1 Mb Up to 2 Mb Up to 4 Mb Storage of phone numbers, system configuration parameters and message address table in some application Easy-to-use and Control • • • • • No compression algorithm development required User-controllable sampling rates Programmable analog interface Standard & Fast mode I2C serial interface (100kHz – 400 kHz) Fully addressable for multiple messages High Quality Solution • • • • High quality voice and music reproduction Nuvoton’s standard 100-year message retention (typical) 100K record cycles (typical) for analog data 10K record cycles (typical) for digital data Options • • • Available in die form ,SOIC and PDIP (ISD5116 Only) Temperature: Commercial – Packaged (0 to +70°C) & die (0 to +50°C); Industrial (-40 to +85°C) Pb-free package Jun 28, 2021 Page 5 of 85 Rev1.6 ISD5100 3. BLOCK DIAGRAM ISD5100-Series Block Diagram FTHRU INP FILTO MICROPHONE MIC IN MIC - 1 (AGPD) AGCCAP AUX IN (S1M0 S1M1 ) FILTO ANA IN 1 (INS0) AUX IN AMP ARRAY 1 (AXPD) 2 SUM1 ARRAY 1 SUM1 MUX 1.0 / 1.4 / 2.0 / 2.8 AUX IN Σ SUM1 MUX SUM1 ( SUM2 ( S1S0 S1S1 ) (ANALOG) CTRL AOS0 AOS1 AOS2 Array I/OMux SUM2 64-bit/samp. ARRAY OUT (ANALOG) ARRAY OUTPUT MUX VOL ARRAY OUT (DIGITAL) ANA IN AMP ANA IN 1 INP ANA IN 2 SUM2 Volume Control 2 1 (VLPD ) 3 VSSA VSSA VSSD VSSD SPEAKER SP+ Spkr. AMP (OPS0 OPS1 ) ( ) SP- VOL0 VOL1 VOL2 2 ( OPA0 OPA1 ) ( VLS0 VLS1 ) Power Conditioning VCCA AUX OUT 2 SUM1 (AIPD) AUX OUT AMP FILTO 64-bit/samp. (DIGITAL) ( AIG0 AIG1 ) Jun 28, 2021 3 ( ) Multilevel/Digital Storage Array Vol MUX 0.625/0.883/1.25/1.76 ANA IN ( S2M0 S2M1 ) ANA OUT- 1 (AOPD) Output MUX XCLK ) SUM2 ANA OUT+ ANA OUT AMP 2 ARRAY INPUT MUX ( AXG0 AXG1) FLD0 FLD1 VOL Σ ANA IN (FLPD) 2 Internal Clock 2 2 1 (FLS0) SUM2 Summing AMP FILTO Low Pass Filter Filter MUX AGC Input Source MUX MIC+ SUM1 Summing AMP INP ANA OUT MUX 6dB Device Control VCCD VCCD SCL Page 6 of 85 SDA INT RAC A0 A1 Rev1.6 ISD5100 4. PIN CONFIGURATION SCL A1 SDA A0 VSSD VSSD NC MIC+ VSSA MICANA OUT+ ANA OUTACAP SP- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 ISD5116 ISD5108 ISD5104 ISD5102 28 27 26 25 24 23 22 21 20 19 18 17 16 VCCD VCCD XCLK INT RAC VSSA 15 VSSA SCL A1 SDA A0 VSSD VSSD NC NC NC AUX OUT AUX IN ANA IN VCCA SP+ MIC+ VSSA MICANA OUT+ ANA OUTACAP SP- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 ISD5116 28 27 26 25 24 23 22 21 20 19 18 17 16 VCCD VCCD XCLK INT RAC VSSA 15 VSSA NC NC AUX OUT AUX IN ANA IN VCCA SP+ SOIC PDIP Jun 28, 2021 Page 7 of 85 Rev1.6 ISD5100 5. PIN DESCRIPTION Pin Name SCL A1 SDA A0 VSSD NC MIC+ VSSA MICANA OUT+ ANA OUTACAP SOIC/PDIP 1 2 3 4 5,6 7,21,22 8 9,15,23 10 11 12 13 SP- 14 SP+ VCCA 16 17 ANA IN AUX IN AUX OUT 18 19 20 RAC 24 INT [1] 25 XCLK 26 VCCD 27,28 Functionality I2C Serial Clock Line: to clock the data into and out of the I2C interface. Input pin that supplies the LSB +1 bit for the I2C Slave Address. I2C Serial Data Line: Data is passed between devices on the bus over this line. Input pin that supplies the LSB for the I2C Slave Address. Digital Ground. No Connect. Differential Positive Input for the microphone amplifier. Analog Ground. Differential Negative Input for the microphone amplifier. Differential Positive Analog Output for ANA OUT. Differential Negative Analog Output for ANA OUT. AGC/AutoMute Capacitor: Required for the on-chip AGC amplifier during record and AutoMute function during playback. Differential Negative Speaker Output: When the speaker outputs are in use, the AUX OUT output is disabled. Differential Positive Speaker Output. Analog Supply Voltage: This pin supplies power to the analog sections of the device. It should be carefully bypassed to Analog Ground to insure correct device operation. Analog Input: one of the analog inputs with selectable gain. Auxiliary Input: one of the analog inputs with selectable gain. Auxiliary Output: one the analog outputs of the device. When this output is used, the SP+ and SP- outputs are disabled. Row Address Clock; an open drain output. The RAC pin goes LOW TRACL[1] before the end of each row of memory and returns HIGH at exactly the end of each row of memory. Interrupt Output; an open drain output that indicates that a set EOM bit has been found during Playback or that the chip is in an Overflow (OVF) condition. This pin remains LOW until a Read Status command is executed. This pin must be grounded for utilizing internal clock. For precision timing control, external clock signal can be applied through this pin. Digital Supply Voltage. These pins supply power to the digital sections of the device. They must be carefully bypassed to Digital Ground to insure correct device operation. See the Parameters section Jun 28, 2021 Page 8 of 85 Rev1.6 ISD5100 6. FUNCTIONAL DESCRIPTION 6.1. OVERVIEW 6.1.1 Speech/Voice Quality The ISD5100 ChipCorder Series can be configured via software to operate at 4.0, 5.3, 6.4 or 8.0 kHz sampling frequency to select appropriate voice quality. Increasing the duration decreases the sampling frequency and bandwidth, which affects audio quality. The table in the following section shows the relationship between sampling frequency, duration and filter pass band. 6.1.2 Duration To meet system requirements, the ISD5100 Series are single-chip solution, which provide 1 to 16 minutes of voice record and playback, depending upon the sample rates chosen. Duration [1] Sample Rate (kHz) ISD5116 ISD5108 ISD5104 ISD5102 Typical Filter Knee (kHz) 8.0 8 min 44 sec 4 min 22 sec 2 min 11 sec 1 min 5 sec 3.4 6.4 10 min 55 sec 5 min 27 sec 2 min 43 sec 1 min 21 sec 2.7 5.3 13 min 6 sec 6 min 33 sec 3 min 17 sec 1 min 38 sec 2.3 17 min 28 sec 8 min 44 sec 4 min 22 sec 2 min 11 sec 1.7 4.0 [1] Minus any pages selected for digital storage 6.1.3 Flash Technology One of the benefits of Nuvoton’s ChipCorder technology is the use of on-chip Flash memory, which provides zero-power message storage. The message is retained for up to 100 years (typically) without power. In addition, the device can be re-recorded over 10,000 times (typically) for the digital data and over 100,000 times (typically) for the analog messages. A new feature has been added that allows memory space in the ISD5100 Series to be allocated to either digital or analog storage when recorded. The fact that a section has been assigned digital or analog data is stored in the Message Address Table by the system microcontroller when the recording is made. 6.1.4 Microcontroller Interface The ISD5100 Series are controlled through an I2C 2-wire interface. This synchronous serial port allows commands, configurations, address data, and digital data to be loaded into the device, while allowing status, digital data and current address information to be read back from the device. In addition to the serial interface, two other status pins can feedback to the microcontroller for enhanced interface. These are the RAC timing pin and the INT pin for interrupts to the controller. Communications with all the internal registers of any operations are through the serial bus, as well as digital memory Read and Write operations. 6.1.5 Programming The ISD5100 Series are also ideal for playback-only applications, where single or multiple messages may be played back when desired. Playback is controlled through the I2C interface. Once the desired Jun 28, 2021 Page 9 of 85 Rev1.6 ISD5100 message configuration is created, duplicates can easily be generated via a third-party programmer. For more information on available application tools and programmers, please see the Nuvoton web site at http://www.nuvoton.com 6.2. FUNCTIONAL DETAILS The ISD5100 Series are single chip solutions for analog and digital data storage. The array can be divided between analog and digital storage according to user’s choice, when the device is configured. The below block diagram shows that the ISD5116 device can be easily designed into a telephone answering machine (TAD). Both Mic inputs transmit the voice input signal from the microphone to perform OGM recording, as well as to record the speech during phone conversation (simplex). When the TAD is activated, the voice of the other party from the phone line feeds into the AUX IN, and is recorded into the ISD5116 device. Then the new messge is usually indicated with blinking new message LED. Hence, during playback, the recorded message is sent out to speaker with volume control. Two I2C pins are used for all communications between the ChipCorder and the microcontroller for analog and/or digital storage, and the two outputs, INT and RAC are feedback to microcontroller for message management. DTMF Detect, Caller ID ANA OUT+ Microcontroller I2C (INT, Display & Push buttons ISD5116 MIC+ MICSP+ SPSpeaker AUX IN NV Memory AUX DAA Phone Line For duplex recording, speech from Mic inputs and message from received path can be directly recorded into the array simultaneously, then playback afterwards. In addition, for speaker phone operation, voice from Mic inputs are fed to AUX OUT and transmitted to the phone line, while message from other party is input from the AUX IN, then fed through to the speaker for listening. The ISD5100 device has the flexibility for other applications, because the audio paths can be configured differently, with each circuit block being powered-up or –down individually, according to the applications requirement. Jun 28, 2021 Page 10 of 85 Rev1.6 ISD5100 6.2.1 Internal Registers The ISD5100 Series have multiple internal registers that are used to store the address information and the configuration or set-up of the device. The two 16-bit configuration registers control the audio paths through the device, the sample frequency, the various gains and attenuations, power up and down of different sections, and the volume settings. These registers are discussed in detail in section 7.3.5. 6.2.2 Memory Architecture The ISD5100 Series memory array are arranged in various pages (or rows) of each 2048 bits as follows. The primary addressing for the pages are handled by 11 bits of address input in the analog mode. A memory page is 2048 bits organized as thirty-two 64-bit "blocks" when used for digital storage. The contents of a page are either analog or digital. This is determined by instruction (opcode) at the time the data is written. A record of where is analog and where is digital, is stored in a message address table (MAT) by the system microcontroller. The MAT is a table kept in the microcontroller memory that defines the status of each message “page”. It can be stored back into the ISD5100 Series if the power fails or the system is turned off. Using this table allows efficient message management. Segments of messages can be stored wherever there is available space in the memory array. [This is explained in detail for the ISD5008 in Applications Note #9 and will be similarly described in a later Note for the ISD5100-Series.] Products Pages (Rows) Bits/Page Memory Size ISD5116 2048 2048 4,194,304 bits ISD5108 1024 2048 2,097,152 bits ISD5104 512 2048 1,048,576 bits ISD5102 256 2048 524,288 bits When a page is used for analog storage, the same 32 blocks are present but there are 8 EOM (End-ofMessage) markers. This means that for each 4 blocks there is an EOM marker at the end. Thus, when recording, the analog recording will stop at any one of eight positions. At 8 kHz sampling frequency, this results in a resolution of 32 msec when ENDING an analog recording. Beginning an analog recording is limited to the 256 msec resolution provided by the 11-bit address. A recording does not immediately stop when the Stop command is given, but continues until the 32 millisecond block is filled. Then a bit is placed in the EOM memory to develop the interrupt that signals a message is finished playing in the Playback mode. Digital data is sent and received serially over the I2C interface. The data is serial-to-parallel converted and stored in one of two alternating (commutating) 64-bit shift registers. When an input register is full, it becomes the register that is parallel written into the array. The prior write register becomes the new serial input register. A mechanism is built-in to ensure there is always a register available for storing new data. Storing data in the memory is accomplished by accepting data one byte at a time and issuing an acknowledge. If data is coming in faster than it can be written, the chip issues an acknowledge to the host microcontroller, but holds SCL LOW until it is ready to accept more data. (See section 7.5.2 for details). The read mode is the opposite of the write mode. Data is read into one of two 64-bit registers from the array and serially sent to the I2C interface. (See section 7.5.3 for details). Jun 28, 2021 Page 11 of 85 Rev1.6 ISD5100 6.3. OPERATIONAL MODES DESCRIPTION 6.3.1 I2C Interface To use more than four ISD5100 Series devices in an application requires some external switching of the I2C interface. I2C interface Important note: The rest of this data sheet will assume that the reader is familiar with the I2C serial interface. Additional information on I2C may be found in section 10 on page 72 of this document. If you are not familiar with this serial protocol, please read this section to familiarize yourself with it. A large amount of additional information on I2C can also be found on the Philips web page at http://www.philips.com/. I2C Slave Address The ISD5100 Series have 7-bit slave address of where x and y are equal to the state, respectively, of the external address pins A1 and A0. Because all data bytes are required to be 8 bits, the LSB of the address byte is the Read/Write selection bit that tells the slave whether to transmit or receive data. Therefore, there are 8 possible slave addresses for the ISD5100-Series. These are: Pinout Table Jun 28, 2021 HEX Value A1 A0 Slave Address 0 0 0 80 0 1 0 82 1 0 0 84 1 1 0 86 0 0 1 81 0 1 1 83 1 0 1 85 1 1 1 87 R/W Bit Page 12 of 85 Rev1.6 ISD5100 ISD5100 Series I2C Operation Definitions There are many control functions used to operate the ISD5100-Series. Among them are: 6.3.1.1. Read Status Command: The Read Status command is a read request from the Host processor to the ISD5100 Series without delivering a Command Byte. The Host supplies all the clocks (SCL). In each case, the entity sending the data drives the data line (SDA). The Read Status Command is executed by the following I2C sequence. 1. Host executes I2C START 2. Send Slave Address with R/W bit = “1” (Read) 81h 3. Slave (ISD5100-Series) responds back to Host an Acknowledge (ACK) followed by 8-bit Status word 4. Host sends an Acknowledge (ACK) to Slave 5. Wait for SCL to go HIGH 6. Slave responds with Upper Address byte of internal address register 7. Host sends an ACK to Slave 8. Wait for SCL to go HIGH 9. Slave responds with Lower Address byte of internal address register (A[4:0] will always return set to 0.) 10. Host sends a NO ACK to Slave, then executes I2C STOP Jun 28, 2021 Page 13 of 85 Rev1.6 ISD5100 Note that the processor could have sent an I2C STOP after the Status Word data transfer and aborted the transfer of the Address bytes. Conventions used in I2C Data Transfer Diagrams = START Condition S A graphical representation of this operation is found below. See the caption box above for more explanation. = STOP Condition P = 8-bit data transfer DATA = “1” in the R/W bit R = “0” in the R/W bit W = ACK (Acknowledge) = No ACK A N = 7-bit Slave Address SLAVE ADDRESS The Box color indicates the direction of data flow = Host to Slave (Gray) = Slave to Host (White) S SLAVE ADDRESS R A Status Jun 28, 2021 DATA A DATA A High Addr. Byte Page 14 of 85 DATA N P Low Addr. Byte Rev1.6 ISD5100 6.3.1.2. Load Command Byte Register (Single Byte Load): A single byte may be written to the Command Byte Register in order to power up the device, start or stop Analog Record (if no address information is needed), or do a Message Cueing function. The Command Byte Register is loaded as follows: S 1. 2. 3. 4. 5. 6. 7. 8. SLAVE ADDRESS W Host executes I2C START Send Slave Address with R/W bit = “0” (Write) [80h] Slave responds back with an ACK. Wait for SCL to go HIGH Host sends a command byte to Slave Slave responds with an ACK Wait for SCL to go HIGH Host executes I2C STOP 6.3.1.3. A DAT A A P Command Byte Load Command Byte Register (Address Load) For the normal addressed mode the Registers are loaded as follows: 1. Host executes I2C START 2. Send Slave Address with R/W bit = “0” (Write) 3. Slave responds back with an ACK. 4. Wait for SCL to go HIGH 5. Host sends a byte to Slave - (Command Byte) 6. Slave responds with an ACK 7. Wait for SCL to go HIGH 8. Host sends a byte to Slave - (High Address Byte) 9. Slave responds with an ACK 10. Wait for SCL to go HIGH 11. Host sends a byte to Slave - (Low Address Byte) 12. Slave responds with an ACK 13. Wait for SCL to go HIGH 14. Host executes I2C STOP S SLAVE W A DATA Command Byte Jun 28, 2021 A DATA A High Addr. Byte Page 15 of 85 DATA A P Low Addr. Byte Rev1.6 ISD5100 6.3.2 I2C Control Registers The ISD5100 Series are controlled by loading commands to, or, reading from, the internal command, configuration and address registers. The Command byte sent is used to start and stop recording, write or read digital data and perform other functions necessary for the operation of the device. Command Byte Control of the ISD5100 Series are implemented through an 8-bit command byte, sent after the 7-bit device address and the 1-bit Read/Write selection bit. The 8 bits are:  Global power up bit  DAB bit: determines whether device is performing an analog or digital function  3 function bits: these determine which function the device is to perform in conjunction with the DAB bit.  3 register address bits: these determine if and when data is to be loaded to a register Power Up Bit C7 C6 C5 C4 C3 C2 C1 C0 PU DAB FN2 FN1 FN0 RG2 RG1 RG0 Function Bits Register Bits Function Bits Function Bits The command byte function bits are detailed in the table to the right. C6, the DAB bit, determines whether the device is performing an analog or digital function. The other bits are decoded to produce the individual commands. Not all decode combinations are currently used, and are reserved for future use. Out of 16 possible codes, the ISD5100 Series uses 7 for normal operation. The other 9 are undefined Jun 28, 2021 Function C6 C5 C4 C3 DAB FN2 FN1 FN0 0 0 0 0 STOP (or do nothing) 0 1 0 1 Analog Play 0 0 1 0 Analog Record 0 1 1 1 Analog MC 1 1 0 0 Digital Read 1 0 0 1 Digital Write 1 0 1 0 Erase (row) Page 16 of 85 Rev1.6 ISD5100 Register Bits The register load may be used to modify a command sequence (such as load an address) or used with the null command sequence to load a configuration or test register. Not all registers are accessible to the user. [RG2 is always 0 as the four additional combinations are undefined.] RG2 RG1 RG0 Function C2 C1 C0 0 0 0 No action 0 0 1 Reserved 0 1 0 Load CFG0 0 1 1 Load CFG1 6.3.3 Opcode Summary OpCode Command Description The following commands are used to access the chip through the I2C interface.  Play: analog play command  Record: analog record command  Message Cue: analog message cue command  Read: digital read command  Write: digital write command  Erase: digital page and block erase command  Power up: global power up/down bit. (C7)  Load CFG0: load configuration register 0  Load CFG1: load configuration register 1  Read STATUS: Read the interrupt status and address register, including a hardwired device ID Jun 28, 2021 Page 17 of 85 Rev1.6 ISD5100 OPCODE COMMAND BYTE TABLE Pwr Function Bits Register Bits OPCODE HEX PU DAB FN2 FN1 FN0 RG2 RG1 RG0 COMMAND BIT NUMBER CMD C7 C6 C5 C4 C3 C2 C1 C0 POWER UP 80 1 0 0 0 0 0 0 0 POWER DOWN 00 0 0 0 0 0 0 0 0 STOP (DO NOTHING) STAY ON 80 1 0 0 0 0 0 0 0 STOP (DO NOTHING) STAY OFF 00 0 0 0 0 0 0 0 0 LOAD CFG0 82 1 0 0 0 0 0 1 0 LOAD CFG1 83 1 0 0 0 0 0 1 1 RECORD ANALOG 90 1 0 0 1 0 0 0 0 RECORD ANALOG @ ADDR 91 1 0 0 1 0 0 0 1 PLAY ANALOG A8 1 0 1 0 1 0 0 0 PLAY ANALOG @ ADDR A9 1 0 1 0 1 0 0 1 MSG CUE ANALOG B8 1 0 1 1 1 0 0 0 MSG CUE ANALOG @ ADDR B9 1 0 1 1 1 0 0 1 ENTER DIGITAL MODE C0 1 1 0 0 0 0 0 0 EXIT DIGITAL MODE 40 0 1 0 0 0 0 0 0 DIGITAL ERASE PAGE D0 1 1 0 1 0 0 0 0 DIGITAL ERASE PAGE @ ADDR D1 1 1 0 1 0 0 0 1 DIGITAL WRITE C8 1 1 0 0 1 0 0 0 DIGITAL WRITE @ ADDR C9 1 1 0 0 1 0 0 1 DIGITAL READ E0 1 1 1 0 0 0 0 0 DIGITAL READ @ ADDR E1 1 1 1 0 0 0 0 1 READ STATUS1 N/A N/A N/A N/A N/A N/A N/A N/A N/A 1. See section 7.2 on page 12 for details. Jun 28, 2021 Page 18 of 85 Rev1.6 ISD5100 6.3.4 Data Bytes I2C In the write mode, the device can accept data sent after the command byte. If a register load option is selected, the next two bytes are loaded into the selected register. The format of the data is MSB first, the I2C standard. Thus to load DATA into the device, DATA is sent first, the byte is acknowledged, and DATA is sent next. The address register consists of two bytes. The format of the address is as follows: ADDRESS = PAGE_ADDRESS, BLOCK_ADDRESS Note: if an analog function is selected, the block address bits must be set to 00000. Digital Read and Write are block addressable. When the device is polled with the Read Status command, it will return three bytes of data. The first byte is the status byte, the next the upper address byte and the last the lower address byte. The status register is one byte long and its bit function is: STATUS = EOM, OVF, READY, PD, PRB, DEVICE_ID Lower address byte will always return the block address bits as zero, either in digital or analog mode. The functions of the bits are: EOM BIT 7 Indicates whether an EOM interrupt has occurred. OVF BIT 6 Indicates whether an overflow interrupt has occurred. READY BIT 5 Indicates the internal status of the device – if READY is LOW no new commands should be sent to device, i.e. Not Ready. PD BIT 4 Device is powered down if PD is HIGH. PRB BIT 3 Play/Record mode indicator. HIGH=Play/LOW=Record. DEVICE_ID BIT 0, 1, 2 An internal device ID. ISD5116 = 001; ISD5104 = 100 and ISD5102 = 101. ISD5108 = 010; It is recommended that you read the status register after a Write or Record operation to ensure that the device is ready to accept new commands. Depending upon the design and the number of pins available on the controller, the polling overhead can be reduced. If INT and RAC are tied to the microcontroller, it does not have to poll as frequently to determine the status of the ISD5100-SERIES. 6.3.5 Configuration Register Bytes The configuration register bytes are defined, in detail, in the drawings of section 7.4 on page 29. The drawings display how each bit enables or disables a function of the audio paths in the ISD5100-Series. The tables below give a general illustration of the bits. There are two configuration registers, CFG0 and CFG1, so there are four 8-bit bytes to be loaded during the set-up of the device. Jun 28, 2021 Page 19 of 85 Rev1.6 ISD5100 Configuration Register 0 (CFG0) D15 D14 D13 D12 D11 D10 D9 D8 D7 D 6 D5 D4 D3 D2 D1 D0 AIG1 AIG0 AIPD AXG1 AXG0 AXPD INS0 AOS2 AOS1 AOS0 AOPD OPS1 OPS0 OPA1 OPA0 VLPD Volume Control Power Down SPKR & AUX OUT Control (2 bits) OUTPUT MUX Select (2 bits) ANA OUT Power Down AUXOUT MUX Select (3 bits) INPUT SOURCE MUX Select (1 bit) AUX IN Power Down AUX IN AMP Gain SET (2 bits) ANA IN Power Down ANA IN AMP Gain SET (2 bits) Configuration Register 1 (CFG1) D15 D14 D13 D12 D11 D10 D9 D8 D7 D 6 D5 D4 D3 D2 D1 D0 VLS1 VLS0 VOL2 VOL1 VOL0 S1S1 S1S0 S1M1 S1M0 S2M1 S2M0 FLS0 FLD1 FLD0 FLPD AGPD AGC AMP Power Down Filter Power Down SAMPLE RATE (& Filter) Set up (2 bits) FILTER MUX Select SUM 2 SUMMING AMP Control (2 bits) SUM 1 SUMMING AMP Control (2 bits) SUM 1 MUX Select (2 bits) VOLUME CONTROL (3 bits) VOLUME CONT. MUX Select (2 bits) Jun 28, 2021 Page 20 of 85 Rev1.6 ISD5100 6.3.6 Power-up Sequence This sequence prepares the ISD5100 Series for an operation to follow, waiting the Tpud time before sending the next command sequence. 1. 2. 3. 4. 5. 6. 7. 8. Send I2C POWER UP Send one byte 10000000 {Slave Address, R/W = 0} 80h Slave ACK Wait for SCL High Send one byte 10000000 {Command Byte = Power Up} 80h Slave ACK Wait for SCL High Send I2C STOP Playback Mode The command sequence for an analog Playback operation can be handled several ways. The most straightforward approach would be to incorporate a single four byte exchange, which consists of the Slave Address (80h), the Command Byte (A9h) for Play Analog @ Address, and the two address bytes. Record Mode The command sequence for an Analog Record would be a four byte sequence consisting of the Slave Address (80h), the Command Byte (91h) for Record Analog @ Address, and the two address bytes. See “Load Command Byte Register (Address Load)” in section 7.3.2 on page 17. 6.3.7 Feed Through Mode The previous examples were dependent upon the device already being powered up and the various paths being set through the device for the desired operation. To set up the device for the various paths requires loading the two 16-bit Configuration Registers with the correct data. For example, in the Feed Through Mode the device only needs to be powered up and a few paths selected. This mode enables the ISD5100 Series to connect to a cellular or cordless base band phone chip set without affecting the audio source or destination. There are two paths involved, the transmit path and the receive path. The transmit path connects the Nuvoton chip’s microphone source through to the microphone input on the base band chip set. The receive path connects the base band chip set’s speaker output through to the speaker driver on the Nuvoton chip. This allows the Nuvoton chip to substitute for those functions and incidentally gain access to the audio to and from the base band chip set. Jun 28, 2021 Page 21 of 85 Rev1.6 ISD5100 To set up the environment described above, a series of commands need to be sent to the ISD5100Series. First, the chip needs to be powered up as described in this section. Then the Configuration Registers must be filled with the specific data to connect the paths desired. In the case of the Feed Through Mode, most of the chip can remain powered down. The following figure illustrates the affected paths. FTHRU ANA OUT MUX 6 dB INP Mic+ FILTO Mic- SUM1 ANA OUT+ ANA OUT- 1 SUM2 3 VOL Chip Set ANA IN Chip Set VOL Microphone OUTPUT MUX ANA IN AMP ANA IN AMP 1 FILTO [AOPD] [AOS2,AOS1,AOS0] Speaker SP+ SP- [APD] SUM2 2 [OPA1,OPA0] The figure above shows the part2 of[AIG1,AIG0] the ISD5100 Series block diagram that is used in Feed Through Mode. The rest of the chip will be powered down to conserve power. The bold lines highlight the audio 2 [OPS1,OPS0] paths. Note that the Microphone to ANA OUT +/– path is differential. To select this mode, the following control bits must be configured in the ISD5100 Series configuration registers. To set up the transmit path: 1. Select the FTHRU path through the ANA OUT MUX—Bits AOS0, AOS1 and AOS2 control the state of the ANA OUT MUX. These are the D6, D7 and D8 bits respectively of Configuration Register 0 (CFG0) and they should all be ZERO to select the FTHRU path. 2. Power up the ANA OUT amplifier—Bit AOPD controls the power up state of ANA OUT. This is bit D5 of CFG0 and it should be a ZERO to power up the amplifier. To set up the receive path: 1. Set up the ANA IN amplifier for the correct gain—Bits AIG0 and AIG1 control the gain settings of this amplifier. These are bits D14 and D15 respectively of CFG0. The input level at this pin determines the setting of this gain stage. The ANA IN Amplifier Gain Settings table on page 36 will help determine this setting. In this example, we will assume that the peak signal never goes above 1 volt p-p single ended. That would enable us to use the 9 dB attenuation setting, or where D14 is ONE and D15 is ZERO. 2. Power up the ANA IN amplifier—Bit AIPD controls the power up state of ANA IN. This is bit D13 of CFG0 and should be a ZERO to power up the amplifier. 3. Select the ANA IN path through the OUTPUT MUX—Bits OPS0 and OPS1 control the state of the OUTPUT MUX. These are bits D3 and D4 respectively of CFG0 and they should be set to the state where D3 is ONE and D4 is ZERO to select the ANA IN path. 4. Power up the Speaker Amplifier—Bits OPA0 and OPA1 control the state of the Speaker and AUX amplifiers. These are bits D1 and D2 respectively of CFG0. They should be set to the state where D1 is ONE and D2 is ZERO. This powers up the Speaker Amplifier and configures it for its higher gain setting for use with a piezo speaker element and also powers down the AUX output stage. The status of the rest of the functions in the ISD5100 Series chip must be defined before the configuration registers settings are updated: Jun 28, 2021 Page 22 of 85 Rev1.6 ISD5100 1. Power down the Volume Control Element—Bit VLPD controls the power up state of the Volume Control. This is bit D0 of CFG0 and it should be set to a ONE to power down this stage. 2. Power down the AUX IN amplifier—Bit AXPD controls the power up state of the AUX IN input amplifier. This is bit D10 of CFG0 and it should be set to a ONE to power down this stage. 3. Power down the SUM1 and SUM2 Mixer amplifiers—Bits S1M0 and S1M1 control the SUM1 mixer and bits S2M0 and S2M1 control the SUM2 mixer. These are bits D7 and D8 in CFG1 and bits D5 and D6 in CFG1 respectively. All 4 bits should be set to a ONE to power down these two amplifiers. 4. Power down the FILTER stage—Bit FLPD controls the power up state of the FILTER stage in the device. This is bit D1 in CFG1 and should be set to a ONE to power down the stage. 5. Power down the AGC amplifier—Bit AGPD controls the power up state of the AGC amplifier. This is bit D0 in CFG1 and should be set to a ONE to power down this stage. 6. Don’t Care bits—The following stages are not used in Feed Through Mode. Their bits may be set to either level. In this example, we will set all the following bits to a ZERO. (a). Bit INS0, bit D9 of CFG0 controls the Input Source Mux. (b). Bits AXG0 and AXG1 are bits D11 and D12 respectively in CFG0. They control the AUX IN amplifier gain setting. (c). Bits FLD0 and FLD1 are bits D2 and D3 respectively in CFG1. They control the sample rate and filter band pass setting. (d). Bit FLS0 is bit D4 in CFG1. It controls the FILTER MUX. (e). Bits S1S0 and S1S1 are bits D9 and D10 of CFG1. They control the SUM1 MUX. (f). Bits VOL0, VOL1 and VOL2 are bits D11, D12 and D13 of CFG1. They control the setting of the Volume Control. (g). Bits VLS0 and VLS1 are bits D14 and D15 of CFG1. They control the Volume Control MUX. The end result of the above set up is CFG0=0100 0100 0000 1011 (hex 440B) and CFG1=0000 0001 1110 0011 (hex 01E3). Since both registers are being loaded, CFG0 is loaded, followed by the loading of CFG1. These two registers must be loaded in this order. The internal set up for both registers will take effect synchronously with the rising edge of SCL. Jun 28, 2021 Page 23 of 85 Rev1.6 ISD5100 6.3.8 Call Record The call record mode adds the ability to record an incoming phone call. In most applications, the ISD5100 Series would first be set up for Feed Through Mode as described above. When the user wishes to record the incoming call, the setup of the chip is modified to add that ability. For the purpose of this explanation, we will use the 6.4 kHz sample rate during recording. The block diagram of the ISD5100 Series shows that the Multilevel Storage array is always driven from the SUM2 SUMMING amplifier. The path traces back from there through the LOW PASS Filter, THE FILTER MUX, THE SUM1 SUMMING amplifier, the SUM1 MUX, then from the ANA in amplifier. Feed Through Mode has already powered up the ANA IN amp so we only need to power up and enable the path to the Multilevel Storage array from that point: 1. Select the ANA IN path through the SUM1 MUX—Bits S1S0 and S1S1 control the state of the SUM1 MUX. These are bits D9 and D10 respectively of CFG1 and they should be set to the state where both D9 and D10 are ZERO to select the ANA IN path. 2. Select the SUM1 MUX input (only) to the S1 SUMMING amplifier—Bits S1M0 and S1M1 control the state of the SUM1 SUMMING amplifier. These are bits D7 and D8 respectively of CFG1 and they should be set to the state where D7 is ONE and D8 is ZERO to select the SUM1 MUX (only) path. 3. Select the SUM1 SUMMING amplifier path through the FILTER MUX—Bit FLS0 controls the state of the FILTER MUX. This is bit D4 of CFG1 and it must be set to ZERO to select the SUM1 SUMMING amplifier path. 4. Power up the LOW PASS FILTER—Bit FLPD controls the power up state of the LOW PASS FILTER stage. This is bit D1 of CFG1 and it must be set to ZERO to power up the LOW PASS FILTER STAGE. 5. Select the 6.4 kHz sample rate—Bits FLD0 and FLD1 select the Low Pass filter setting and sample rate to be used during record and playback. These are bits D2 and D3 of CFG1. To enable the 6.4 kHz sample rate, D2 must be set to ONE and D3 set to ZERO. 6. Select the LOW PASS FILTER input (only) to the S2 SUMMING amplifier—Bits S2M0 and S2M1 control the state of the SUM2 SUMMING amplifier. These are bits D5 and D6 respectively of CFG1 and they should be set to the state where D5 is ZERO and D6 is ONE to select the LOW PASS FILTER (only) path. In this mode, the elements of the original PASS THROUGH mode do not change. The sections of the chip not required to add the record path remain powered down. In fact, CFG0 does not change and remains CFG0=0100 0100 0000 1011 (hex 440B). CFG1 changes to CFG1=0000 0000 1100 0101 (hex 00C5). Since CFG0 is not changed, it is only necessary to load CFG1. Note that if only CFG0 was changed, it would be necessary to load both registers. Jun 28, 2021 Page 24 of 85 Rev1.6 ISD5100 6.3.9 Memo Record The Memo Record mode sets the chip up to record from the local microphone into the chip’s Multilevel Storage Array. A connected cellular telephone or cordless phone chip set may remain powered down and is not active in this mode. The path to be used is microphone input to AGC amplifier, then through the INPUT SOURCE MUX to the SUM1 SUMMING amplifier. From there the path goes through the FILTER MUX, the LOW PASS FILTER, the SUM2 SUMMING amplifier, then to the MULTILEVEL STORAGE ARRAY. In this instance, we will select the 5.3 kHz sample rate. The rest of the chip may be powered down. 1. Power up the AGC amplifier—Bit AGPD controls the power up state of the AGC amplifier. This is bit D0 of CFG1 and must be set to ZERO to power up this stage. 2. Select the AGC amplifier through the INPUT SOURCE MUX—Bit INS0 controls the state of the INPUT SOURCE MUX. This is bit D9 of CFG0 and must be set to a ZERO to select the AGC amplifier. 3. Select the INPUT SOURCE MUX (only) to the S1 SUMMING amplifier—Bits S1M0 and S1M1 control the state of the SUM1 SUMMING amplifier. These are bits D7 and D8 respectively of CFG1 and they should be set to the state where D7 is ZERO and D8 is ONE to select the INPUT SOURCE MUX (only) path. 4. Select the SUM1 SUMMING amplifier path through the FILTER MUX—Bit FLS0 controls the state of the FILTER MUX. This is bit D4 of CFG1 and it must be set to ZERO to select the SUM1 SUMMING amplifier path. 5. Power up the LOW PASS FILTER—Bit FLPD controls the power up state of the LOW PASS FILTER stage. This is bit D1 of CFG1 and it must be set to ZERO to power up the LOW PASS FILTER STAGE. 6. Select the 5.3 kHz sample rate—Bits FLD0 and FLD1 select the Low Pass filter setting and sample rate to be used during record and playback. These are bits D2 and D3 of CFG1. To enable the 5.3 kHz sample rate, D2 must be set to ZERO and D3 set to ONE. 7. Select the LOW PASS FILTER input (only) to the S2 SUMMING amplifier—Bits S2M0 and S2M1 control the state of the SUM2 SUMMING amplifier. These are bits D5 and D6 respectively of CFG1 and they should be set to the state where D5 is ZERO and D6 is ONE to select the LOW PASS FILTER (only) path. To set up the chip for Memo Record, the configuration registers are set up as follows: CFG0=0010 0100 0010 0001 (hex 2421). CFG1=0000 0001 0100 1000 (hex 0148). Only those portions necessary for this mode are powered up. Jun 28, 2021 Page 25 of 85 Rev1.6 ISD5100 6.3.10 Memo and Call Playback This mode sets the chip up for local playback of messages recorded earlier. The playback path is from the MULTILEVEL STORAGE ARRAY to the FILTER MUX, then to the LOW PASS FILTER stage. From there, the audio path goes through the SUM2 SUMMING amplifier to the VOLUME MUX, through the VOLUME CONTROL then to the SPEAKER output stage. We will assume that we are driving a piezo speaker element. This audio was previously recorded at 8 kHz. All unnecessary stages will be powered down. 1. Select the MULTILEVEL STORAGE ARRAY path through the FILTER MUX—Bit FLS0, the state of the FILTER MUX. This is bit D4 of CFG1 and must be set to ONE to select the MULTILEVEL STORAGE ARRAY. 2. Power up the LOW PASS FILTER—Bit FLPD controls the power up state of the LOW PASS FILTER stage. This is bit D1 of CFG1 and it must be set to ZERO to power up the LOW PASS FILTER STAGE. 3. Select the 8.0 kHz sample rate—Bits FLD0 and FLD1 select the Low Pass filter setting and sample rate to be used during record and playback. These are bits D2 and D3 of CFG1. To enable the 8.0 kHz sample rate, D2 and D3 must be set to ZERO. 4. Select the LOW PASS FILTER input (only) to the S2 SUMMING amplifier —Bits S2M0 and S2M1 control the state of the SUM2 SUMMING amplifier. These are bits D5 and D6 respectively of CFG1 and they should be set to the state where D5 is ZERO and D6 is ONE to select the LOW PASS FILTER (only) path. 5. Select the SUM2 SUMMING amplifier path through the VOLUME MUX—Bits VLS0 and VLS1 control the state VOLUME MUX. These bits are bits D14 and D15, respectively of CFG1. They should be set to the state where D14 is ONE and D15 is ZERO to select the SUM2 SUMMING amplifier. 6. Power up the VOLUME CONTROL LEVEL—Bit VLPD controls the power-up state of the VOLUME CONTROL attenuator. This is Bit D0 of CFG0. This bit must be set to a ZERO to power-up the VOLUME CONTROL. 7. Select a VOLUME CONTROL LEVEL—Bits VOL0, VOL1, and VOL2 control the state of the VOLUME CONTROL LEVEL. These are bits D11, D12, and D13, respectively, of CFG1. A binary count of 000 through 111 controls the amount of attenuation through that state. In most cases, the software will select an attenuation level according to the desires of the current users of the product. In this example, we will assume the user wants an attenuation of –12 dB. For that setting, D11 should be set to ONE, D12 should be set to ONE, and D13 should be set to a ZERO. 8. Select the VOLUME CONTROL path through the OUTPUT MUX—These are bits D3 and D4, respectively, of CFG0. They should be set to the state where D3 is ZERO and D4 is a ZERO to select the VOLUME CONTROL. 9. Power up the SPEAKER amplifier and select the HIGH GAIN mode—Bits OPA0 and OPA1 control the state of the speaker (SP+ and SP–) and AUX OUT outputs. These are bits D1 and D2 of CFG0. They must be set to the state where D1 is ONE and D2 is ZERO to power-up the speaker outputs in the HIGH GAIN mode and to power-down the AUX OUT. To set up the chip for Memo or Call Playback, the configuration registers are set up as follows: CFG0=0010 0100 0010 0100 (hex 2424). CFG1=0101 1001 1101 0001 (hex 59D1). Only those portions necessary for this mode are powered up. Jun 28, 2021 Page 26 of 85 Rev1.6 ISD5100 6.3.11 Message Cueing Message cueing allows the user to skip through analog messages without knowing the actual physical location of the message. This operation is used during playback. In this mode, the messages are skipped 512 times faster than in normal playback mode. It will stop when an EOM marker is reached. Then, the internal address counter will be pointing to the next message. 6.4. ANALOG MODE 6.4.1 Aux In and Ana In Description The AUX IN is an additional audio input to the ISD5100-Series, such as from the microphone circuit in a mobile phone “car kit.” This input has a nominal 694 mV p-p level at its minimum gain setting (0 dB). See the AUX IN Amplifier Gain Settings table on page 37. Additional gain is available in 3 dB steps (controlled by the I2C serial interface) up to 9 dB. Internal to the device Rb CCOUP=0.1 µF Ra AUX IN Input AUX IN Input Amplifier NOTE: fCUTOFF= Jun 28, 2021 1 2πRaCCOUP Page 27 of 85 Rev1.6 ISD5100 The ANA IN pin is the analog input from the telephone chip set. It can be switched (by the serial bus) to the speaker output, the array input or to various other paths. This pin is designed to accept a nominal 1.11 Vp-p when at its minimum gain (6 dB) setting. See the ANA IN Amplifier Gain Settings table on page 37. There is additional gain available in 3 dB steps controlled from the I2C interface, if required, up to 15 dB. Internal to the device Rb CCOUP=0.1 µF Ra ANA IN Input ANA IN Input Amplifier 1 2πRaCCOUP 6.4.2 ISD5100 Series Analog Structure (left half) Description NOTE: fCUTOFF= INP SUM1 SUMMING AMP INPUT SOURCE MUX AGC AMP Σ SUM1 AUX IN AMP 2 (S1M1,S1M0) (INS0) SUM1 MUX FILTO S1M1 S1M0 0 0 BOTH 0 1 SUM1 MUX ONLY 1 0 INP Only 1 1 Power Down ANA IN AMP ARRAY INSO Source 0 AGC AMP 1 AUX IN AMP 15 14 13 AIG1 AIG0 AIPD 12 15 14 13 VLS1 VLS0 VOL2 VOL1 12 S1S1 S1S0 0 0 ANA IN 0 1 ARRAY 1 0 FILTO 1 1 N/C 2 (S1S1,S1S0) 11 AXG1 AXG0 11 VOL0 10 9 AXPD INS0 10 S1S1 8 AOS2 9 8 S1 S0 S1M1 7 6 5 AOS1 AOS0 AOPD 7 SOURCE 6 5 S1 M0 S2 M1 S2M0 SOURCE 4 3 2 OPS1 OPS0 OPA1 1 0 4 3 2 1 0 FLS0 FLD1 FLD0 FLPD AGPD OPA0 VLPD C FG0 C FG1 6.4.3 ISD5100 Series Aanalog Structure (right half) Description Jun 28, 2021 Page 28 of 85 Rev1.6 ISD5100 FILTO FILTO FILTER FILTER SUM2 SUMMING AMP MUX MUX SUM1 LOW PASS FILTER Σ ARRAY FLS0 SOURCE 0 SUM1 1 ARRAY FLPD SUM2 1 1 (FLS0) (FLPD) 2 (S2M1,S2M0) CONDITION 0 Power Up 1 ANA IN AMP Power Down FLD1 FLD0 SAMPLE RATE FILTER BANDWIDTH 0 0 0 8 KHz 3.6 KHz 1 6.4 KHz 2.9 KHz 1 0 5.3 KHz 2.4 KHz 1 1 4.0 KHz 1.8 KHz 15 14 VLS1 VLS0 13 VOL2 12 11 VOL1 VOL0 Jun 28, 2021 S2M0 0 0 SOURCE BOTH 0 1 ANA IN ONLY 1 0 FILTO ONLY 1 1 Power Down MULTILEVEL STORAGE ARRAY INTERNAL CLOCK XCLK S2M1 2 (FLD1,FLD0) ARRAY 10 9 S1S1 S1S0 8 7 6 S1 M1 S1M0 S2M1 5 4 3 2 S2 M0 FLS0 FLD1 FLD0 Page 29 of 85 1 0 FLPD AGPD CFG1 Rev1.6 ISD5100 6.4.4 Volume Control Description VOL MUX ANA IN AMP SUM2 SUM1 VOLUME CONTROL VOL INP 2 (VLS1,VLS0) VLS1 VLS0 SOURCE AIG1 AIG0 AIPD 15 14 VLS1 VLS0 Jun 28, 2021 13 VOL2 0 0 ANA IN AMP 0 1 SUM2 1 0 SUM1 1 1 INP AXG1 AXG0 AXPD INS0 12 11 VOL1 VOL0 10 S1 S1 VLPD 3 1 (VLPD) (VOL2,VOL1,VOL0) AOS2 9 8 S1S0 S1M1 Power Up 1 Power Down VOL2 VOL1 VOL0 ATTENUATION 0 0 0 0 dB 0 0 1 4 dB 0 1 0 8 dB 0 1 1 12 dB 1 0 0 16 dB 1 0 1 20 dB 1 1 0 24 dB 1 1 1 28 dB AOS1 AOS0 7 CONDITION 0 6 S1 M0 S2M1 Page 30 of 85 AOPD OPS1 OPS0 OPA1 OPA0 VLPD 5 4 3 2 1 0 S2M0 FLS0 FLD1 FLD0 FLPD AGPD CFG0 CFG1 Rev1.6 ISD5100 6.4.5 Speaker and Aux Out Description Car Kit AUX OUT (1 Vp -p Ma x) OUTPUT MUX VOL ANA IN AMP Sp eaker SP+ FILTO SP– 2 (OPA1, OPA0) SUM2 2 (OPS1,OPS0) OPA1 13 15 14 AIG1 AIG0 AIPD 12 11 10 Jun 28, 2021 Power Down Power Down SOURCE 0 1 3.6 VP-P @ 150 Ω Power Down 1 0 23.5 mWatt @ 8 Ω Power Down 1 1 Power Down 1 VP-P Max @ 5 KΩ OPS0 0 0 VOL 0 1 ANA IN 1 0 FILTO 1 1 SUM2 9 8 AOS2 7 AUX OUT 0 OPS1 AXG1 AXG0 AXPD INS0 OPA0 SPKR DRIVE 0 6 AOS1 AOS0 5 4 3 AOPD OPS1 OPS0 Page 31 of 85 2 1 0 OPA1 OPA0 VLPD CFG0 Rev1.6 ISD5100 6.4.6 Ana Out Description * FTHRU (1 Vp -p m a x. from AUX IN o r ARRAY) (69 4 mVp-p ma x. fro m mi crop ho ne inp ut) * INP * VOL Chip Set ANA OUT+ * FILTO ANA OUT– * SUM1 1 (AOPD) * SUM2 3 (AOS2,AOS1,AOS0) AOS2 AOS1 AOS0 SOURCE 0 0 0 FTHRU 0 0 1 INP 0 1 0 VOL 0 1 1 FILTO 1 0 0 SUM1 1 0 1 SUM2 1 1 0 N/C 1 1 1 N/C *DIFFERENTIAL PATH 15 14 13 AIG1 AIG0 AIPD 12 11 AOPD 10 AXG1 AXG0 AXPD 9 INS0 8 7 AOS2 AOS1 6 5 AOS0 AOPD 4 OPS1 3 2 OPS0 OPA1 CONDITION 0 Power Up 1 Power Down 1 0 OPA0 VLPD CFG0 6.4.7 Analog Inputs Microphone Inputs The microphone inputs transfer the voice signal to the on-chip AGC preamplifier or directly to the ANA OUT MUX, depending on the selected path. The direct path to the ANA OUT MUX has a gain of 6 dB so a 208 mV p-p signal across the differential microphone inputs would give 416 mV p-p across the ANA OUT pins. The AGC circuit has a range of 45 dB in order to deliver a nominal 694 mV p-p into the storage array from a typical electric microphone output of 2 to 20 mV p-p. The input impedance is typically 10kΩ. The ACAP pin provides the capacitor connection for setting the parameters of the microphone AGC circuit. It should have a 4.7 µF capacitor connected to ground. It cannot be left floating. This is because the capacitor is also used in the playback mode for the AutoMute circuit. This circuit reduces the amount of noise present in the output during quiet pauses. Tying this pin to ground gives maximum gain; to VCCA gives minimum gain for the AGC amplifier but will cancel the AutoMute function. Jun 28, 2021 Page 32 of 85 Rev1.6 ISD5100 * FTHRU 6 dB AGPD MIC+ AGCIN MIC AGC MIC– CONDITION 0 Power Up 1 Power Down 1 (AGPD) To AutoMute ACAP (Playb ack Only) * Diffe re ntial Path 15 14 VLS1 VLS0 13 12 11 VOL2 VOL1 VOL0 10 S1 S1 7 9 8 S1S0 S1M1 6 4 3 2 1 0 FLS0 FLD1 FLD0 FLPD AGPD 5 S1 M0 S2M1 S2M0 CFG1 ANA IN (Analog Input) The ANA IN pin is the analog input from the telephone chip set. It can be switched (by the I2C interface) to the speaker output, the array input or to various other paths. This pin is designed to accept a nominal 1.11 V p-p when at its minimum gain (6 dB) setting. There is additional gain available, if required, in 3 dB steps, up to 15 dB. The gain settings are controlled from the I2C interface. Internal to the device Rb CCOUP = 0.1 µF ANA IN Input Ra ANA IN Input Amplifier Gain Setting 00 01 10 Resistor Ratio (Rb/Ra) 63.9 / 102 77.9 / 88.1 92.3 / 73.8 0.625 0.883 1.250 Gain2 (dB) -4.1 -1.1 1.9 11 106 / 60 1.767 4.9 Gain Note: Ra & Rb are in kΩ NOTE: fCUTTOFF 1 2xRaCCOU ANA IN Amplifier Gain Settings Setting(1) 0TLP Input VP-P(3) 6 dB 9 dB 12 dB 1.110 0.785 0.555 CFG0 AIG1 0 0 1 AIG0 0 1 0 Gain(2) Array In/Out VP-P Speaker Out VP-P(4) 0.625 0.883 1.250 0.694 0.694 0.694 2.22 2.22 2.22 1. Gain from ANA IN to SP+/0.393 1 1 1.767 0.694 2.22 2. Gain from ANA IN to ARRAY IN 3. 0TLP Input is the reference Transmission Level Point that is used for testing. This level is typically 3 dB below clipping 4. Speaker Out gain set to 1.6 (High). (Differential) 15 dB Jun 28, 2021 Page 33 of 85 Rev1.6 ISD5100 AUX IN (Auxiliary Input) The AUX IN is an additional audio input to the ISD5100-Series, such as from the microphone circuit in a mobile phone “car kit.” This input has a nominal 694 mV p-p level at its minimum gain setting (0 dB). See the following table. Additional gain is available in 3 dB steps (controlled by the I2C interface) up to 9 dB. AUX IN Input Modes Internal to the device Rb CCOUP = 0.1 µF AUX IN Input Ra ANA IN Input Amplifier Gain Setting 00 01 Resistor Ratio (Rb/Ra) 40.1 / 40.1 47.0 / 33.2 1.0 1.414 Gain(2) (dB) 0 3 10 11 53.5 / 26.7 59.2 / 21 2.0 2.82 6 9 Gain Note: Ra & Rb are in kΩ NOTE: fCUTTOFF 1 2xRaCCOU AUX IN Amplifier Gain Settings Setting(1) 0 dB 3 dB 6 dB 9 dB 0TLP Input VP-P(3) 0.694 0.491 0.347 0.245 CFG0 AXG1 0 0 1 1 AXG0 0 1 0 1 Gain(2) Array In/Out VP-P Speaker Out VP-P(4) 1.00 1.41 2.00 2.82 0.694 0.694 0.694 0.694 0.694 0.694 0.694 0.694 1. Gain from AUX IN to ANA OUT 2. Gain from AUX IN to ARRAY IN 3. 0TLP Input is the reference Transmission Level Point that is used for testing. This level is typically 3 dB below clipping 4. Differential Jun 28, 2021 Page 34 of 85 Rev1.6 ISD5100 6.5. DIGITAL MODE 6.5.1 Erasing Digital Data The Digital Erase command can only erase an entire page at a time. This means that the D1 command only needs to include the 11-bit page address; the 5-bit for block address are left at 00000. Once a page has been erased, each block may be written separately, 64 bits at a time. But, if a block has been previously written then the entire page of 2048 bits must be erased in order to re-write (or change) a block. A sequence might be look like: - read the entire page - store it in RAM - change the desired bit(s) - erase the page - write the new data from RAM to the entire page 6.5.2 Writing Digital Data The Digital Write function allows the user to select a portion of the array to be used as digital memory. The partition between analog and digital memory is left up to the user. A page can only be either Digital or Analog, but not both. The minimum addressable block of memory in the digital mode is one block or 64 bits, when reading or writing. The address sent to the device is the 11-bit row (or page) address with the 5-bit scan (or block) address. However, one must send a Digital Erase before attempting to change digital data on a page. This means that even when changing only one of the 32 blocks, all 32 blocks will need to be rewritten to the page. Command Sequence: The chip enters digital mode by sending the ENTER DIGITAL MODE command from power down. Send the DIGITAL WRITE @ ADDR command with the row address. After the address is entered, the data is sent in one-byte packets followed by an I2C acknowledge generated by the chip. Data for each block is sent MSB first. The data transfer is ended when the master generates an I2C STOP condition. If only a partial block of data is sent before the STOP condition, “zero” is written in the remaining bytes; that is, they are left at the erase level. An erased page (row) will be read as all zeros. The device can buffer up to two blocks of data. If the device is unable to accept more data due to the internal write process, the SCL line will be held LOW indicating to the master to halt data transfer. If the device encounters an overflow condition, it will respond by generating an interrupt condition and an I2C Not Acknowledge signal after the last valid byte of data. Once data transfer is terminated, the device needs up to two cycles (64 us) to complete its internal write cycle before another command is sent. If an active command is sent before the internal cycle is finished, the part will hold SCL LOW until the current command is finished. After writing is complete, send the EXIT DIGITAL MODE command. 6.5.3 Reading Digital Data The Digital Read command utilizes the combined I2C command format. That is, a command is sent to the chip using the write data direction. Then the data direction is reversed by sending a repeated start condition, and the slave address with R/W set to 1. After this, the slave device (ISD5100-Series) begins to send data to the master until the master generates a NACK. If the part encounters an overflow condition, the INT pin is pulled LOW. No other communication with the master is possible due to the master generating ACK signals. Digital Write and Digital Read can be done a “block” at a time. Thus, only 64 bits need be read in each Digital Read command sequence. 6.5.4 Example Command Sequences An explanation and graphical representation of the Erase, Write and Read operations are found below. Jun 28, 2021 Page 35 of 85 Rev1.6 ISD5100 Note: All sequences assumes that the chip is in power-down mode before the commands are sent. 6.5.4.1. Erase ===== I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0xc0) WaitACK WaitSCLHigh I2CStop Erase Digital Data - Write, Slave address zero - Enter Digital Mode Command I2CStart SendByte(0x80) - Write, Slave address zero WaitACK WaitSCLHigh SendByte(0xd1) - Digital Erase Command WaitACK WaitSCLHigh SendByte(row/256) - high address byte WaitACK WaitSCLHigh SendByte(row%256) - low address byte WaitACK WaitSCLHigh I2CStop repeat until the number of RAC pulses are one less than the number of rows to delete { wait RAC low WAIT RAC high } Note: If only one row is going to be erased, send the following STOP command immediately after ERASE command and skip the loop above I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0xc0) Jun 28, 2021 - Write, Slave address zero - Stop digital erase Page 36 of 85 Rev1.6 ISD5100 WaitACK WaitSCLHigh I2CStop wait until erase of the last row has completed { wait RAC low WAIT RAC high } I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0x40) WaitACK WaitSCLHigh I2Cstop - Write, Slave address zero - Exit Digital Mode Command Notes 1. Erase operations must be addressed on a Row boundary. The 5 LSB bits of the Low Address Byte will be ignored. 2. I2C bus is released while erase proceeds. Other devices may use the bus until it is time to execute the STOP command that causes the end of the Erase operation. 3. Host processor must count RAC cycles to determine where the chip is in the erase process, one row per RAC cycle. RAC pulses LOW for 0.25 millisecond at the end of each erased row. The erase of the "next" row begins with the rising edge of RAC. See the Digital Erase RAC timing diagram on page 51. 4. When the erase of the last desired row begins, the following STOP command (Command Byte = 80 hex) must be issued. This command must be completely given, including receiving the ACK from the Slave before the RAC pin goes HIGH at the end of the row. S SLAVE W A CON A P Erase starts on falling edge of Slave acknowledge S SLAVE ADDRESS W A D1h Jun 28, 2021 A DATA A DATA A P Note 2 Page 37 of 85 Command Byte High Addr. Byte Rev1.6 Low Addr. Byte ISD5100 Jun 28, 2021 Page 38 of 85 Rev1.6 ISD5100 SUGGESTED FLOW FOR DIGITAL ERASE IN ISD5100-Series 80,C0 ENTER DIGITAL MODE TO ERASE MULTIPLE (n) PAGES (ROWS) 80,D1,nn,nn SEND ERASE COMMAND COMMANDS NO 80 = PowerUp or Stop C0 = Enter Digital Mode D1 = Erase Digital Page@ 40 = Exit Digital Mode COUNT RAC FOR n-1 RAC\ ~ 250 uS YES 80,C0 SEND STOP COMMAND BEFORE NEXT RAC SEND STOP COMMAND BEFORE RAC NO WAIT FOR RAC NO WAIT FOR RAC RAC\ ~ 125 uS RAC\ ~ 125 uS YES YES 80,40 80,C0 EXIT DIGITAL MODE STOP COMMAND MUST BE FINISHED BEFORE RAC\ RISES RAC\ SIGNAL 6/20/2002 BOJ Revision B Jun 28, 2021 DEVICE POWERS DOWN AUTOMATICALLY 250 uS 125 uS 1.25 ms Page 39 of 85 Rev1.6 ISD5100 6.5.4.2. Write Digital Data Write ===== I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0xc0) WaitACK WaitSCLHigh I2CStop - Write, Slave address zero - Enter Digital Mode Command I2CStart SendByte(0x80) - Write, Slave address zero WaitACK WaitSCLHigh SendByte(0xc9) - Write Digital Data Command WaitACK WaitSCLHigh SendByte(row/256) - high address byte WaitACK WaitSCLHigh SendByte(row%256) - low address byte WaitACK WaitSCLHigh repeat until all data is sent { SendByte(data) - send data byte WaitACK() WaitSCLHigh() } I2CStop I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0x40) WaitACK WaitSCLHigh I2CStop - Write, Slave address zero - Exit Digital Mode Command S Jun 28, 2021 SLAVE W A CON Page 40 of 85 A P Rev1.6 ISD5100 Jun 28, 2021 Page 41 of 85 Rev1.6 ISD5100 SUGGESTED FLOW FOR DIGITAL WRITE IN ISD5100-Series 80,C0 80,C9,nn,nn ENTER DIGITAL MODE SEND WRITE COMMAND W/ START ADDRESS COMMANDS 80 = PowerUp or Stop C0 = Enter Digital Mode C9 = Write Digital Page@ 40 = Exit Digital Mode SEND DATA BYTE (SEND NEXT BYTE) WAIT for SCL HIGH NO BYTE COUNTER =256? YES 80,40 6/24/2002 BOJ Revision N/C Jun 28, 2021 EXIT DIGITAL MODE DEVICE POWERS DOWN AUTOMATICALLY Page 42 of 85 Rev1.6 ISD5100 6.5.4.3. Read Digital Data Read ===== I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0xc0) WaitACK WaitSCLHigh I2CStop - Write, Slave address zero - Enter Digital Mode I2CStart SendByte(0x80) - Write, Slave address zero WaitACK WaitSCLHigh SendByte(0xe1) - Read Digital Data Command WaitACK WaitSCLHigh SendByte(row/256) - high address byte WaitACK WaitSCLHigh() SendByte(row%256) - low address byte WaitACK WaitSCLHigh I2CStart SendByte(0x81) - Send repeat start command - Read, Slave address zero repeat until all data is read { data = ReadByte() - send clocks to read data byte SendACK - send NACK on the last byte WaitSCLHigh - The only flow control available } I2CStop() I2CStart SendByte(0x80) WaitACK WaitSCLHigh SendByte(0x40) WaitACK WaitSCLHigh Jun 28, 2021 - Write, Slave address zero - Exit Digital Mode Page 43 of 85 Rev1.6 ISD5100 I2CStop S S SLAVE W W A SLAVE E1h Command A CON A A DAT A DAT Addr. A Low Addr. S R A SLAVE S Jun 28, 2021 SLAVE DAT A DAT W A Page 44 of 85 A 40h ~ ~ ~ High P DAT A P N P Rev1.6 ISD5100 SUGGESTED FLOW FOR DIGITAL READ IN ISD5100-Series 80,C0 80,E1,nn,nn ENTER DIGITAL MODE SEND READ COMMAND W/ START ADDRESS COMMANDS 80 = PowerUp or Stop C0 = Enter Digital Mode E1 = Read Digital Page@ 40 = Exit Digital Mode READ DATA BYTE (READ NEXT BYTE) WAIT for SCL HIGH NO BYTE COUNTER =256? YES 80,40 6/24/2002 BOJ Revision N/C Jun 28, 2021 EXIT DIGITAL MODE DEVICE POWERS DOWN AUTOMATICALLY Page 45 of 85 Rev1.6 ISD5100 6.6. PIN DETAILS 6.6.1 Digital I/O Pins SCL (Serial Clock Line) The Serial Clock Line is a bi-directional clock line. It is an open-drain line requiring a pull-up resistor to Vcc. It is driven by the "master" chips in a system and controls the timing of the data exchanged over the Serial Data Line. SDA (Serial Data Line) The Serial Data Line carries the data between devices on the I2C interface. Data must be valid on this line when the SCL is HIGH. State changes can only take place when the SCL is LOW. This is a bidirectional line requiring a pull-up resistor to Vcc. RAC (Row Address Clock) RAC is an open drain output pin that normally marks the end of a row. At the 8 kHz sample frequency, the duration of this period is 256 ms. RAC stays HIGH for 248 ms and stays LOW for the remaining 8 ms before it reaches the end of a row. There are 2048 rows of memory in the ISD5116 devices, 1024 rows in the ISD5108, 512 rows in the ISD5104 and 256 rows in the ISD5102. 1 ROW RAC Waveform During 8 KHz Operation 256 msec TRAC 8 msec TRACL The RAC pin remains HIGH for 500 µsec and stays LOW for 15.6 µsec under the Message Cueing mode. See the Timing Parameters table on page 64 for RAC timing information at other sample rates. When a record command is first initiated, the RAC pin remains HIGH for an extra TRACML period, to load sample and hold circuits internal to the device. The RAC pin can be used for message management techniques. 1 ROW RAC Waveform During Message Cueing @ 8KHz Operation 500 usec TRACM Jun 28, 2021 Page 46 of 85 15.6 us TRACML Rev1.6 ISD5100 RAC Waveform During Digital Erase @ 8kHz Operation 1.25 ms TRACE .25 ms TRACEL INT (Interrupt) INT is an open drain output pin. The ISD5100 Series interrupt pin goes LOW and stays LOW when an Overflow (OVF) or End of Message (EOM) marker is detected. Each operation that ends in an EOM or OVF generates an interrupt, including the message cueing cycles. The interrupt is cleared by a READ STATUS instruction that will give a status byte out the SDA line. XCLK (External Clock Input) This is the external clock input. To use internal clock, this pin must be grounded (suggest connecting to VSSD). While in internal clock mode, the ISD5100 Series are operated at one of four internal rates selected for its internal oscillator by the Sample Rate Select bits. For precision timing control, external clock signal can be applied through this pin. In the external clock mode, the device can be clocked through the XCLK pin at 4.096 MHz as described in section 7.4.3 on page 32. Because the anti-aliasing and smoothing filters track the Sample Rate Select bits, one must, for optimum performance, maintain the external clock at 4.096 MHz AND set the Sample Rate Configuration bits to one of the four values to properly set the filters to the correct cutoff frequency as described in section 7.4.3 on page 32. The duty cycle on the input clock is not critical, as the clock is immediately divided by two internally. External Clock Input Table ISD5116 Duration (Minutes) ISD5108 Duration (Minutes) ISD5104 Duration (Minutes) ISD5102 Duration (Minutes) Sample Rate (kHz) Required Clock (kHz) FLD1 FLD0 Filter Knee (kHz) 8.73 4.36 2.18 1.08 8.0 4096 0 0 3.4 10.9 5.45 2.72 1.35 6.4 4096 0 1 2.7 13.1 6.55 3.27 1.63 5.3 4096 1 0 2.3 17.5 8.75 4.37 2.18 4.0 4096 1 1 1.7 Jun 28, 2021 Page 47 of 85 Rev1.6 ISD5100 A0, A1 (Address Pins) These two pins are normally strapped for the desired address that the ISD5100 Series will have on the I2C serial interface. If there are four of these devices on the bus, then each must be strapped differently in order to allow the Master device to address them individually. The possible addresses range from 80h to 87h, depending upon whether the device is being written to, or read from, by the host. The ISD5100 Series have a 7-bit slave address of which only A0 and A1 are pin programmable. The eighth bit (LSB) is the R/W bit. Thus, the address will be 1000 0xy0 or 1000 0xy1. (See the table in section 7.3.1 on page 13.) 6.6.2 Analog I/O Pins MIC+, MIC- (Microphone Input +/-) The microphone input transfers the voice signal to the on-chip AGC preamplifier or directly to the ANA OUT MUX, depending on the selected path. The direct path to the ANA OUT MUX has a gain of 6 dB so a 208 mV p-p signal across the differential microphone inputs would give 416 mV p-p across the ANA OUT pins. The AGC circuit has a range of 45 dB in order to deliver a nominal 694 mV p-p into the storage array from a typical electret microphone output of 2 to 20 mV p-p. The input impedance is typically 10kΩ. 1.5k Internal to the device MIC+ 220 µF + 1.5k CCOUP=0.1 Electret Microphone WM-54B Panasonic 01 6 dB FTHRU AGC MIC IN Ra=10k 10kΩ 1.5k 1 NOTE: fCUTOFF= MIC- 2πRaCCOUP ANA OUT+, ANA OUT- (Analog Output +/-) This differential output is designed to go to the microphone input of the telephone chip set. It is designed to drive a minimum of 5 kΩ between the “+” and “–” pins to a nominal voltage level of 694 mV p-p. Both pins have DC bias of approximately 1.2 VDC. The AC signal is superimposed upon this analog ground voltage. These pins can be used single-ended, getting only half the voltage. Do NOT ground the unused pin. ACAP (AGC Capacitor) This pin provides the capacitor connection for setting the parameters of the microphone AGC circuit. It should have a 4.7 µF capacitor connected to ground. It cannot be left floating. This is because the capacitor is also used in the playback mode for the AutoMute circuit. This circuit reduces the amount of noise present in the output during quiet pauses. Tying this pin to ground gives maximum gain; tying it to VCCA gives minimum gain for the AGC amplifier but cancels the AutoMute function. SP +, SP- (Speaker +/-) Jun 28, 2021 Page 48 of 85 Rev1.6 ISD5100 This is the speaker differential output circuit. It is designed to drive an 8Ω speaker connected across the speaker pins up to a maximum of 23.5 mW RMS power. This stage has two selectable gains, 1.32 and 1.6, which can be chosen through the configuration registers. These pins are biased to approximately 1.2 VDC and, if used single-ended, must be capacitively coupled to their load. Do NOT ground the unused pin. AUX OUT (Auxiliary Output) The AUX OUT is an additional audio output pin to be used, for example, to drive the speaker circuit in a “car kit.” It drives a minimum load of 5kΩ and up to a maximum of 1V p-p. The AC signal is superimposed on approximately 1.2 VDC bias and must be capacitively coupled to the load. Car Kit AUX OUT (1 Vp -p Max) OUTPUT MUX VOL ANA IN AMP FILTO SP– 2 (OPA1, OPA0) SUM2 OPS1 OPS0 Speaker SP+ SOURCE 2 (OPS1,OPS0) OPA1 OPA0 SPKR DRIVE AUX OUT 0 0 VOL 0 0 Power Down Power Down 0 1 ANA IN 0 1 3.6 Vp.p @150Ω Power Down 1 0 FILTO 1 0 23.5 mWatt @ 8Ω Power Down 1 1 SUM2 1 1 Power Down 15 14 AIG1 AIG0 AIPD 13 12 11 10 9 AXG1 AXG0 AXPD INS0 Jun 28, 2021 8 7 6 5 4 3 AOS2 AOS1 AOS0 AOPD OPS1 OPS0 Page 49 of 85 2 1 1 Vp.p Max @ 5KΩ 0 OPA1 OPA0 VLPD CFG0 Rev1.6 ISD5100 ANA IN (Analog Input) The ANA IN pin is the analog input from the telephone chip set. It can be switched (by the I2C interface) to the speaker output, the array input or to various other paths. This pin is designed to accept a nominal 1.11 V p-p when at its minimum gain (6 dB) setting. There is additional gain available, if required, in 3 dB steps, up to 15 dB. The gain settings are controlled from the I2C interface. ANA IN Input Modes Internal to the device Rb CCOUP = 0.1 ìF ANA IN Input Gain Setting Resistor Ration (Rb/Ra) Gain Gain2 (dB) 00 63.9 / 102 0.625 -4.1 01 77.9 / 88.1 0.88 -1.1 10 92.3 / 73.8 1.25 1.9 11 106 / 60 1.77 4.9 Ra ANA IN Input Amplifier Note: Ra & Rb are in kΩ NOTE: fCUTTOFF 1 2xRaCCCUP ANA IN Amplifier Gain Settings Setting(1) 1. 2. 3. 4. 0TLP Input VP-P(3) CFG0 6 dB 9 dB 1.110 0.785 AIG1 0 0 12 dB 15 dB 0.555 0.393 1 1 Gain(2) Array In/Out VP-P Speaker Out VP-P(4) AIG0 0 1 0.625 0.883 0.694 0.694 2.22 2.22 0 1 1.250 1.767 0.694 0.694 2.22 2.22 Gain from ANA IN to SP+/Gain from ANA IN to ARRAY IN 0TLP Input is the reference Transmission Level Point that is used for testing. This level is typically 3 dB below clipping Speaker Out gain set to 1.6 (High). (Differential) Jun 28, 2021 Page 50 of 85 Rev1.6 ISD5100 AUX IN (Auxiliary Input) The AUX IN is an additional audio input to the ISD5100-Series, such as from the microphone circuit in a mobile phone “car kit.” This input has a nominal 694 mV p-p level at its minimum gain setting (0 dB). See the AUX IN Amplifier Gain Settings table on page 56. Additional gain is available in 3 dB steps (controlled by the I2C interface) up to 9 dB. AUX IN Input Modes Internal to the device Rb CCOUP = 0.1 ìF Ra AUX IN Input ANA IN Input Amplifier NOTE: fCUTTOFF 1 Gain Setting 00 01 Resistor Ratio (Rb/Ra) 40.1 / 40.1 47.0 / 33.2 1.0 1.414 Gain(2) (dB) 0 3 10 11 53.5 / 26.7 59.2 / 21 2.0 2.82 6 9 Gain Note: Ra & Rb are in kΩ 2xRaCCCUP AUX IN Amplifier Gain Settings Setting(1) 0TLP Input VP-P(3) 0 dB 3 dB 0.694 0.491 AXG1 0 0 6 dB 9 dB 0.347 0.245 1 1 Gain(2) AXG0 0 1 Array In/Out VP-P Speaker Out VP-P(4) 1.00 1.41 0.694 0.694 0.694 0.694 0 1 2.00 2.82 0.694 0.694 0.694 0.694 CFG0 1. Gain from AUX IN to ANA OUT 2. Gain from AUX IN to ARRAY IN 3. 0TLP Input is the reference Transmission Level Point that is used for testing. This level is typically 3 dB below clipping 4. Differential Jun 28, 2021 Page 51 of 85 Rev1.6 ISD5100 6.6.3 Power and Ground Pins VCCA, VCCD (Voltage Inputs) To minimize noise, the analog and digital circuits in the ISD5100 Series devices use separate power busses. These +3 V busses lead to separate pins. Tie the VCCD pins together as close as possible and decouple both supplies as near to the package as possible. VSSA, VSSD (Ground Inputs) The ISD5100 Series utilizes separate analog and digital ground busses. The analog ground (VSSA) pins should be tied together as close to the package as possible and connected through a low-impedance path to power supply ground. The digital ground (VSSD) pin should be connected through a separate low impedance path to power supply ground. These ground paths should be large enough to ensure that the impedance between the VSSA pins and the VSSD pin is less than 3Ω. The backside of the die is connected to VSSD through the substrate resistance. In a chip-on-board design, the die attach area must be connected to VSSD. NC (Not Connect) These pins should not be connected to the board at any time. Connection of these pins to any signal, ground or VCC, may result in incorrect device behavior or cause damage to the device. Jun 28, 2021 Page 52 of 85 Rev1.6 ISD5100 6.6.4 PCB Layout Examples For SOIC package : PC board traces and the three chip capacitors are on the bottom side of the board. 1 Note 3 Note V S S D (Digital Ground) 1 Note 1: VSSD traces should be kept separated back to the VSS supply feed point.. Note 2: VCCD traces should be kept separate back to the VCC Supply feed point. Note 3: The Digital and Analog grounds tie together at the power supply. The VCCA and VCCD supplies will also need filter capacitors per good engineering practice (typ. 50 to 100 uF). Jun 28, 2021 Note 2 O O O O O O O O O O O O O O C1 C2 C3 O O O O O O O O O O O O O O Analog Ground Page 53 of 85 V C C D XCLK VSSA C1=C2=C3=0.1 uF chip Capacitors To VCCA Note 3 Rev1.6 ISD5100 7. TIMING DIAGRAMS 7.1 I2C TIMING DIAGRAM STOP START t t t f r SU-DAT SDA SCL t t HIGH f t t LOW SU-STO t SCLK Jun 28, 2021 Page 54 of 85 Rev1.6 ISD5100 I2C INTERFACE TIMING STANDARDMODE PARAMETER FAST-MODE UNIT SYMBOL MIN. MAX. MIN. MAX. fSCL 0 100 0 400 kHz tHD-STA 4.0 - 0.6 - μs LOW period of the SCL clock tLOW 4.7 - 1.3 - μs HIGH period of the SCL clock tHIGH 4.0 - 0.6 - μs Set-up time for a repeated START condition tSU-STA 4.7 - 0.6 - μs Data set-up time tSU-DAT 250 - 100(1) - ns Rise time of both SDA and SCL signals tr - 1000 20 + 0.1Cb(2) 300 ns Fall time of both SDA and SCL signals tf - 300 20 + 0.1Cb(2) 300 ns Set-up time for STOP condition tSU-STO 4.0 - 0.6 - μs tBUF 4.7 - 1.3 - μs Capacitive load for each bus line Cb - 400 - 400 pF Noise margin at the LOW level for each connected device (including hysteresis) VnL 0.1 VDD - 0.1 VDD - V Noise margin at the HIGH level for each connected device (including hysteresis) VnH 0.2 VDD - 0.2 VDD - V SCL clock frequency Hold time (repeated) START condition. After this period, the first clock pulse is generated Bus-free time between a STOP and START condition 1. A Fast-mode I2C-interface device can be used in a Standard-mode I2C-interface system, but the requirement tSU;DAT > 250 ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line; tr max + tSU;DAT = 1000 + 250 = 1250 ns (according to the Standard-mode I2C -interface specification) before the SCL line is released. 2. Cb = total capacitance of one bus line in pF. If mixed with HS mode devices, faster fall-times are allowed. Jun 28, 2021 Page 55 of 85 Rev1.6 ISD5100 7.2 PLAYBACK AND STOP CYCLE tSTOP tSTART SDA SCL PLAY AT ADDR STOP DATA CLOCK PULSES STOP ANA IN ANA OUT Jun 28, 2021 Page 56 of 85 Rev1.6 ISD5100 7.3 EXAMPLE OF POWER UP COMMAND (FIRST 12 BITS) Jun 28, 2021 Page 57 of 85 Rev1.6 ISD5100 8. ABSOLUTE MAXIMUM RATINGS ABSOLUTE MAXIMUM RATINGS (PACKAGED PARTS)(1) Condition Junction temperature 1500C Storage temperature range -650C to +1500C Voltage Applied to any pins (VSS - 0.3V) to (VCC + 0.3V) Voltage applied to any pin (Input current limited to +/-20 mA) (VSS – 1.0V) to (VCC + 1.0V) Lead temperature (soldering 3000C – 10 seconds) VCC - VSS 1. Value -0.3V to +5.5V Stresses above those listed may cause permanent damage to the device. Exposure to the absolute maximum ratings may affect device reliability. Functional operation is not implied at these conditions. ABSOLUTE MAXIMUM RATINGS (DIE)(1) Condition 1. Value Junction temperature 1500C Storage temperature range -650C to +1500C Voltage Applied to any pads (VSS - 0.3V) to (VCC + 0.3V) VCC - VSS -0.3V to +5.5V Stresses above those listed may cause permanent damage to the device. Exposure to the absolute maximum ratings may affect device reliability. Functional operation is not implied at these conditions. Jun 28, 2021 Page 58 of 85 Rev1.6 ISD5100 OPERATING CONDITIONS (PACKAGED PARTS) Conditions Values Commercial operating temperature [1] 0°C to +70°C Supply voltage (VCC) [2] +2.7V to +3.3V Ground voltage (VSS) [3] 0V Voltage Applied to any pins (VSS - 0.3V) to (VCC + 0.3V) Conditions Industrial operating temperature Supply voltage (VCC) [2] Values [1] -40°C to +85°C ISD5102, ISD5104, ISD5116 +2.7V to +3.3V ISD5108 +2.7V to +3.6V Ground voltage (VSS) [3] 0V Voltage Applied to any pins (VSS - 0.3V) to (VCC + 0.3V) OPERATING CONDITIONS (DIE) Conditions Die operating temperature range Values [1] 0°C to +50°C Supply voltage (VCC) [2] +2.7V to +3.3V Ground voltage (VSS) [3] 0V Voltage Applied to any pads (VSS - 0.3V) to (VCC + 0.3V) [1] Case temperature Jun 28, 2021 [2] VCC = VCCA = VCCD [3] Page 59 of 85 VSS = VSSA = VSSD Rev1.6 ISD5100 9. ELECTRICAL CHARACTERISTICS 9.1. GENERAL PARAMETERS Min(2) Typ(1) Max(2) Units VCC x 0.2 V Symbol Parameters VIL Input Low Voltage VIH Input High Voltage VOL SCL, SDA Output Low Voltage 0.4 V IOL = 3 µA VIL2V Input low interface 0.4 V Apply only SCL, SDA to VIH2V Input high voltage for 2V interface V Apply only SCL, SDA to VOL1 RAC, INT Output Low Voltage V IOL = 1 mA VOH Output High Voltage V IOL = -10 µA ICC VCC Current (Operating) - Playback - Record - Feedthrough 15 30 12 25 40 15 mA mA mA No Load(3) No Load(3) No Load(3) ISB VCC Current (Standby) 1 10 µA [3] IIL Input Leakage Current ±1 µA voltage VCC x 0.8 for Conditions V 2V 1.6 0.4 VCC – 0.4 [1] Typical values: TA = 25°C and Vcc = 3.0 V. All min/max limits are guaranteed by Nuvoton via electrical testing or characterization. Not all specifications are 100 percent tested. [3] All VCC and VSS are connected appropriately and others are floated. [2] Jun 28, 2021 Page 60 of 85 Rev1.6 ISD5100 9.2. TIMING PARAMETERS Symbol Parameters FS Sampling Frequency FCF Filter Knee 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) TREC TPLAY TPUD TSTOP/ PAUSE TRAC TRACL TRACM Min(2) Typ(1) Max(2) Units 8.0 6.4 5.3 4.0 kHz kHz kHz kHz (5) (5) (5) (5) 3.4 2.7 2.3 1.7 kHz kHz kHz kHz Knee Point(3)(7) Knee Point(3)(7) Knee Point(3)(7) Knee Point(3)(7) min min min min (6) (6) (6) (6) min min min min (6) (6) (6) (6) Record Duration 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) ISD5116 ISD5108 ISD5104 ISD5102 8.73 10.9 13.1 17.5 4.36 5.45 6.55 8.75 2.18 2.72 3.27 4.37 1.08 1.35 1.63 2.18 Playback Duration 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) ISD5116 ISD5108 ISD5104 ISD5102 8.73 10.9 13.1 17.5 4.36 5.45 6.55 8.75 2.18 2.72 3.27 4.37 1.08 1.35 1.63 2.18 Power-Up Delay 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 1 1 1 1 msec msec msec msec Stop or Pause Record or Play 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 32 40 48 64 msec msec msec msec RAC Clock Period 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 256 320 384 512 msec msec msec msec RAC Clock Low Time 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 8 10 12.1 16 msec msec msec msec RAC Clock Period in Message Cueing Mode 8.0 kHz (sample rate) 500 µsec Jun 28, 2021 Conditions Page 61 of 85 (9) (9) (9) (9) Rev1.6 ISD5100 TRACML TRACE TRACEL THD 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 625 750 1000 µsec µsec µsec RAC Clock Low Time in Message Cueing Mode 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 15.6 19.5 23.4 31.2 µsec µsec µsec µsec RAC Clock Period in Digital Erase Mode 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 1.25 1.56 1.87 2.50 msec msec msec msec RAC Clock Low Time in Digital Erase mode 8.0 kHz (sample rate) 6.4 kHz (sample rate) 5.3 kHz (sample rate) 4.0 kHz (sample rate) 0.25 0.31 0.37 0.50 msec msec msec msec Total Harmonic Distortion ANA IN to ARRAY, ARRAY to SPKR 1 1 Jun 28, 2021 Page 62 of 85 2 2 % % @1 kHz at 0TLP, sample rate = 5.3 kHz Rev1.6 ISD5100 9.3. ANALOG PARAMETERS MICROPHONE INPUT(14) Symbol Parameters VMIC+/- MIC +/- Input Voltage VMIC (0TLP) MIC +/- input reference transmission level point (0TLP) AMIC Gain from MIC +/- input to ANA OUT AMIC (GT) MIC +/- Gain Tracking RMIC Microphone input resistance AAGC Microphone AGC Amplifier Range Min Typ Max (2) (1)(14) (2) Conditions mV Peak-to-Peak(4)(8) mV Peak-to-Peak(4)(10) dB 1 kHz at VMIC (0TLP)(4) +/0.1 dB 1 kHz, +3 to –40 dB 0TLP Input 10 kΩ MIC- and MIC+ pins 40 dB Over 3-300 mV Range Units 300 208 5.5 Units 6.0 6 6.5 ANA IN(14) Symbol Parameters VANA IN ANA IN Input Voltage VANA IN ANA IN (0TLP) Input Voltage Min Typ Max (2) (1)(14) (2) 1.6 Conditions V Peak-to-Peak (6 dB gain setting) 1.1 V Peak-to-Peak (6 dB gain setting)(10) (0TLP) AANA IN (sp) Gain from ANA IN to SP+/- +6 to +15 dB 4 Steps of 3 dB AANA IN (AUX Gain from ANA IN to AUX OUT -4 to +5 dB 4 Steps of 3 dB dB (11) OUT) AANA IN (GA) ANA IN Gain Accuracy AANA IN (GT) ANA IN Gain Tracking +/0.1 dB 1000 Hz, +3 to –45 dB 0TLP Input, 6 dB setting RANA IN ANA IN Input Resistance (6 dB to +15 dB) 10 to 100 kΩ Depending on ANA IN Gain Jun 28, 2021 -0.5 +0.5 Page 63 of 85 Rev1.6 ISD5100 AUX IN(14) Symbol Parameters Min Typ Max (2) (1)(14) (2) Unit s Conditions 1.0 V Peak-to-Peak (0 dB gain setting) VAUX IN AUX IN Input Voltage VAUX IN (0TLP) AUX IN (0TLP) Input Voltage 694.2 mV Peak-to-Peak (0 dB gain setting) AAUX IN (ANA Gain from AUX IN to ANA OUT 0 to +9 dB 4 Steps of 3 dB dB (11) OUT) AAUX IN (GA) AUX IN Gain Accuracy -0.5 +0.5 AAUX IN (GT) AUX IN Gain Tracking +/0.1 dB 1000 Hz, +3 to –45 dB 0TLP Input, 0 dB setting RAUX IN AUX IN Input Resistance 10 to 100 kΩ Depending on AUX IN Gain SPEAKER OUTPUTS(14) Symbol Parameters Min Typ Max (2) (1)(14) (2) Units VSPHG SP+/- Output Voltage (High Gain Setting) RSPLG SP+/- Output Load Imp. (Low Gain) 8 RSPHG SP+/- Output Load Imp. (High Gain) 70 CSP SP+/- Output Load Cap. VSPAG SP+/- Output Bias Voltage (Analog Ground) VSPDCO Speaker Output DC Offset +/100 mV DC ICNANA ANA IN to SP+/- Idle Channel Noise -65 dB Speaker Load = 150Ω(12)(13) SP+/- to ANA OUT Cross Talk -65 dB 1 kHz 0TLP input to ANA IN, with MIC+/- and AUX IN AC coupled to VSS, and measured at ANA OUT feed through mode (12) IN/(SP+/-) CRT(SP+/)/ANA OUT 3.6 Conditions 150 100 V Peak-to-Peak, differential load = 150Ω, OPA1, OPA0 = 01 Ω OPA1, OPA0 = 10 Ω OPA1, OPA0 = 01 pF 1.2 VDC With ANA IN to Speaker, ANA IN AC coupled to VSSA PSRR Power Supply Rejection Ratio -55 dB Measured with a 1 kHz, 100 mV p-p sine wave input at VCC and VCC pins FR Frequency Response (300-3400 Hz) +0.5 dB With 0TLP input to ANA IN, 6 dB setting (12) Guaranteed by design POUTLG Power Output (Low Gain Setting) Jun 28, 2021 23.5 mW RMS Page 64 of 85 Differential load at 8Ω Rev1.6 ISD5100 SINAD SINAD ANA IN to SP+/- 62.5 dB 0TLP ANA In input minimum gain, 150Ω load (12)(13) ANA OUT (14) Symbol Parameters Min (2) Typ e Max Units Conditions (2) (1)(14) SINAD SINAD, MIC IN to ANA OUT 62.5 dB Load = 5kΩ(12)(13) SINAD SINAD, AUX IN to ANA OUT (0 to 9 dB) 62.5 dB Load = 5kΩ(12)(13) ICONIC/ANA Idle Channel Noise – Microphone -65 dB Load = 5kΩ(12)(13) Idle Channel Noise – AUX IN (0 to 9 dB) -65 dB Load = 5kΩ(12)(13) Measured with a 1 kHz, 100 mV P-P sine wave to VCCA, VCCD pins OUT ICN AUX IN/ANA OUT Power Supply Rejection Ratio -40 dB VBIAS ANA OUT+ and ANA OUT- 1.2 VDC Inputs AC coupled to VSSA VOFFSET ANA OUT+ to ANA OUT- mV DC Inputs AC coupled to VSSA RL Minimum Load Impedance kΩ Differential Load FR Frequency Response (3003400 Hz) dB 0TLP input to MIC+/- in feedthrough mode. 0TLP input to AUX IN in feedthrough mode(12) CRTANA ANA OUT to SP+/Cross Talk -65 dB 1 kHz 0TLP output from ANA OUT, with ANA IN AC coupled to VSSA, and measured at SP+/-(12) ANA OUT to AUX OUT Cross Talk -65 dB 1 kHz 0TLP output from ANA OUT, with ANA IN AC coupled to VSSA, and measured at AUX OUT(12) PSRR (ANA OUT) OUT/(SP+/-) CRTANA OUT/AUX OUT Jun 28, 2021 +/100 5 +0.5 Page 65 of 85 Rev1.6 ISD5100 AUX OUT(14) Symbol Parameters VAUX OUT AUX OUT – Maximum Output Swing RL Minimum Load Impedance CL Maximum Load Capacitance VBIAS AUX OUT SINAD SINAD – ANA IN to AUX OUT ICN(AUX OUT) Idle Channel Noise – ANA IN to AUX OUT CRTAUX AUX OUT to ANA OUT Cross Talk OUT/ANA OUT Jun 28, 2021 Min Typ Max (2) (1(14)) (2) Units 1.0 V 5 Conditions 5kΩ Load KΩ 100 1.2 pF VDC 62.5 dB 0TLP ANA IN input, minimum gain, 5k load(12)(13) -65 dB Load=5kΩ(12)(13) -65 dB 1 kHz 0TLP input to ANA IN, with MIC +/- and AUX IN AC coupled to VSSA, measured at SP+/-, load = 5kΩ. Referenced to nominal 0TLP @ output Page 66 of 85 Rev1.6 ISD5100 VOLUME CONTROL(14) Symbol AOUT Parameters Min Typ Max (2) (1)(14) (2) Output Gain Tolerance for each step Unit s -28 to 0 -1.0 +1.0 Conditions dB 8 steps of 4 dB, referenced to output dB ANA IN 1.0 kHz 0TLP, 6 dB gain setting measured differentially at SP+/- Conditions 1. 2. 13. Typical values: TA = 25°C and Vcc = 3.0V. All min/max limits are guaranteed by Nuvoton via electrical testing or characterization. Not all specifications are 100 percent tested. Low-frequency cut off depends upon the value of external capacitors (see Pin Descriptions). Differential input mode. Nominal differential input is 208 mV p-p. (0TLP) Sampling frequency can vary as much as –6/+4 percent over the industrial temperature and voltage ranges. For greater stability, an external clock can be utilized (see Pin Descriptions). Playback and Record Duration can vary as much as –6/+4 percent over the industrial temperature and voltage ranges. For greater stability, an external clock can be utilized (See Pin Descriptions). Filter specification applies to the low pass filter. For optimal signal quality, this maximum limit is recommended. When a record command is sent, TRAC = TRAC + TRACL on the first page addressed. The maximum signal level at any input is defined as 3.17 dB higher than the reference transmission level point. (0TLP) This is the point where signal clipping may begin. Measured at 0TLP point for each gain setting. See the ANA IN table and AUX IN table on pages 54 and 55 respectively. 0TLP is the reference test level through inputs and outputs. See the ANA IN table and AUX IN table on pages 54 and 55 respectively. Referenced to 0TLP input at 1 kHz, measured over 300 to 3,400 Hz bandwidth. 14. For die, only typical values are applicable. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. Jun 28, 2021 Page 67 of 85 Rev1.6 ISD5100 9.4. CHARACTERISTICS OF THE I2C SERIAL INTERFACE The I2C interface is for bi-directional, two-line communication between different ICs or modules. The two lines are a serial data line (SDA) and a serial clock line (SCL). Both lines must be connected to a positive supply via a pull-up resistor. Data transfer may be initiated only when the interface bus is not busy. Bit transfer One data bit is transferred during each clock pulse. The data on the SDA line must remain stable during the HIGH period of the clock pulse, as changes in the data line at this time will be interpreted as a control signal. SDA SCL data line stable; data valid changed of data allowed Bit transfer on the I2CStart and stop conditions Both data and clock lines remain HIGH when the interface bus is not busy. A HIGH-to-LOW transition of the data line while the clock is HIGH is defined as the start condition (S). A LOW-to-HIGH transition of the data line while the clock is HIGH is defined as the stop condition (P). SDA SDA SCL S P START condition System configuration SCL STOP condition Definition of START and STOP conditions A device generating a message is a ‘transmitter’; a device receiving a message is the ‘receiver’. Th Jun 28, 2021 Page 68 of 85 Rev1.6 ISD5100 System Configuration A device generating a message is a ‘transmitter’; a device receiving a message is the ‘receiver’. The device that controls the message I sthe ‘master’ and the devices that are controlled by the master are the ‘slaves’. LCD DRIVER MICROCONTROLLER STATIC RAM OR EEPROM SDA SCL GATE ARRAY ISD 5116 Example of an I2C-bus configuration using two microcontrollers Acknowledge The number of data bytes transferred between the start and stop conditions from transmitter to receiver is unlimited. Each byte of eight bits is followed by an acknowledge bit. The acknowledge bit is a HIGH level signal put on the interface bus by the transmitter during which time the master generates an extra acknowledge related clock pulse. A slave receiver which is addressed must generate an acknowledge after the reception of each byte. In addition, a master receiver must generate an acknowledge after the reception of each byte that has been clocked out of the slave transmitter. The device that acknowledges must pull down the SDA line during the acknowledge clock pulse so that the SDA line is stable LOW during the HIGH period of the acknowledge related clock pulse (set-up and hold times must be taken into consideration). A master receiver must signal an end of data to the transmitter by not generating an acknowledge on the last byte that has been clocked out of the slave. In this event, the transmitter must leave the data line HIGH to enable the master to generate a stop condition. DATA OUTPUT BY TRANSMITTER not acknowledge DATA OUTPUT BY RECEIVER acknowledge 8 SCL FROM MASTER 1 2 9 S dock pulse for acknowledgement START condition Acknowledge on the I2C-bus Jun 28, 2021 Page 69 of 85 Rev1.6 ISD5100 9.5. I2C PROTOCOL Since the I2C protocol allows multiple devices on the bus, each device must have an address. This address is known as a “Slave Address”. A Slave Address consists of 7 bits, followed by a single bit that indicates the direction of data flow. This single bit is 1 for a Write cycle, which indicates the data is being sent from the current bus master to the device being addressed. This single bit is a 0 for a Read cycle, which indicates that the data is being sent from the device being addressed to the current bus master. For example, the valid Slave Addresses for the ISD5100 Series device, for both Write and Read cycles, are shown in section 7.3.1 on page 13 of this datasheet. Before any data is transmitted on the I2C interface, the current bus master must address the slave it wishes to transfer data to or from. The Slave Address is always sent out as the 1st byte following the Start Condition sequence. An example of a Master transmitting an address to a ISD5100 Series slave is shown below. In this case, the Master is writing data to the slave and the R/W bit is “0”, i.e. a Write cycle. All the bits transferred are from the Master to the Slave, except for the indicated Acknowledge bits. The following example details the transfer explained in section 7.3.1-2-3 on pages 13-20 of this datasheet. Master Transmits to Slave Receiver (Write) Mode acknowledgement from slave S SLAVE ADDRESS Start Bit W A acknowledgement from slave COMMAND BYTE A acknowledgement from slave High ADDR. BYTE A acknowledgement from slave Low ADDR. BYTE A P Stop Bit R/W A common procedure in the ISD5100 Series is the reading of the Status Bytes. The Read Status condition in the ISD5100 Series is triggered when the Master addresses the chip with its proper Slave Address, immediately followed by the R/W bit set to a “1” and without the Command Byte being sent. This is an example of the Master sending to the Slave, immediately followed by the Slave sending data back to the Master. The “N” not-acknowledge cycle from the Master ends the transfer of data from the Slave. The following example details the transfer explained in section 7.3.1 on page 13 of this datasheet. Jun 28, 2021 Page 70 of 85 Rev1.6 ISD5100 Master Reads from Slave immediately after first byte (Read Mode) acknowledgement from slave From Slave From Slave S R A SLAVE ADDRESS A STATUS WORD From Slave High ADDR. BYTE A N Low ADDR BYTE P From Master Start Bit From Master acknowledgement from Master acknowledgement from Master R/W From Master Stop Bit From Master not-acknowledged from Master Another common operation in the ISD5100 Series is the reading of digital data from the chip’s memory array at a specific address. This requires the I2C interface Master to first send an address to the ISD5100 Series Slave device, and then receive data from the Slave in a single I2C operation. To accomplish this, the data direction R/W bit must be changed in the middle of the command. The following example shows the Master sending the Slave address, then sending a Command Byte and 2 bytes of address data to the ISD5100-Series, and then immediately changing the data direction and reading some number of bytes from the chip’s digital array. An unlimited number of bytes can be read in this operation. The “N” not-acknowledge cycle from the Master forces the end of the data transfer from the Slave. The following example details the transfer explained in section 7.5.4 on page 47 of this datasheet. Master Reads from the Slave after setting data address in Slave (Write data address, READ Data) acknowledgement from slave S SLAVE ADDRESS Start Bit From Master W A acknowledgement from slave COMMAND BYTE A acknowledgement from slave High ADDR. BYTE A acknowledgement from slave Low ADDR. BYTE A R/W From Master acknowledgement from slave From Slave S SLAVE ADDRESS R A 8 BITS of DATA From Slave A 8 BITS of DATA From Slave A 8 BITS of DATA N P From Master Start Bit From Master R/W From Master acknowledgement from Master acknowledgement from Master Stop Bit From Master not-acknowled from Master Jun 28, 2021 Page 71 of 85 Rev1.6 ISD5100 10. TYPICAL APPLICATION CIRCUIT The following typical application example on ISD5100 series is for references only. They make no representation or warranty that such applications shall be suitable for the use specified. It’s customer’s obligation to verify the design in its own system for the functionalities, voice quality, current consumption, and etc. In addition, the below notes apply to the following application examples: * The suggested values are for references only. Depending on system requirements, they can be adjusted for functionalities and better performance. It is important to have a separate path for each ground and power back to the related terminals to minimize the noise. Besides, the power supplies should be decoupled as close to the device as possible. Also, it is crucial to follow good audio design practices in layout and power supply decoupling. See recommendations in Application Notes from our websites. Example #1: Recording via microphone VCC 1 2 3 4 26 To μC I2C Interface & Address Setting VCC 1.5kΩ * 1.5k Ω * 220 μ F* Electret microphone 1.5kΩ * μ C I/O 0.1μF* 0.1μF* 4.7μF* 8 10 13 18 19 VCCD SCL SDA A1 A0 XCLK VCCD VSSD VSSD VCCA VSSA VSSA MIC+ VSSA 5100 MIC- RAC INT ANA OUT+ ACAP ANA OUT- ANA IN AUX OUT AUX IN SP+ SP- 27 28 5 6 17 9 15 23 24 25 0.1μF 0.1μF To μ C I/O for message management (optional) 11 12 20 16 14 SOIC / PDIP Jun 28, 2021 Page 72 of 85 Rev1.6 ISD5100 11. PACKAGE SPECIFICATION 11.1. 28-LEAD 300-MIL PLASTIC SMALL OUTLINE INTEGRATED CIRCUIT (SOIC) 28 27 26 25 24 23 22 21 20 19 18 17 16 15 2 3 4 5 1 6 7 8 9 10 11 12 13 14 A G C B D E H F Plastic Small Outline Integrated Circuit (SOIC) Dimensions INCHES MILLIMETERS Min Nom Max Min Nom Max A 0.701 0.706 0.711 17.81 17.93 18.06 B 0.097 0.101 0.104 2.46 2.56 2.64 C 0.292 0.296 0.299 7.42 7.52 7.59 D 0.005 0.009 0.0115 0.127 0.22 0.29 E 0.014 0.016 0.019 0.35 0.41 0.48 F 0.050 1.27 G 0.400 0.406 0.410 10.16 10.31 10.41 H 0.024 0.032 0.040 0.61 0.81 1.02 Note: Lead coplanarity to be within 0.004 inches. Jun 28, 2021 Page 73 of 85 Rev1.6 ISD5100 11.2. 28-LEAD 600-MIL PLASTIC DUAL INLINE PACKAGE (PDIP) Plastic Dual Inline Package (PDIP) (P) Dimensions INCHES A B1 B2 C1 C2 D D1 E F G H J S 0 Jun 28, 2021 Min 1.445 0.065 0.600 0.530 0.015 0.125 0.015 0.055 0.008 0.070 0° Nom 1.450 0.150 0.070 0.540 0.018 0.060 0.100 0.010 0.075 MILLIMETERS Max 1.455 Min 36.70 0.075 0.625 0.550 0.19 1.65 15.24 13.46 0.135 0.022 0.065 0.38 3.18 0.38 1.40 0.012 0.080 15° 0.20 1.78 0° Page 74 of 85 Nom 36.83 3.81 1.78 13.72 0.46 1.52 2.54 0.25 1.91 Max 36.96 1.91 15.88 13.97 4.83 3.43 0.56 1.65 0.30 2.03 15° Rev1.6 ISD5100 11.3. ISD5116 DIE INFORMATION VSSD VSSD SDA A0 VCCD INT SCL VCCD XCLK A1 RAC VSSA ISD5116 Device Die Dimensions X: 4125 µm Y: 8030 µm Die Thickness [3] 292.1 µm ± 12.7 µm ≈ Pad Opening Single pad: 90 x 90 µm Double pad: 180 x 90 µm VSSA MIC + MIC - ≈ ISD5116 ANA OUT - ANA OUT + SP ACAP VSSA [2] VCCA [2] SP + ANA IN AUX OUT AUX IN Notes 1. The backside of die is internally connected to Vss. It MUST NOT be connected to any other potential or damage may occur. 2. Double bond recommended, if treated as single doubled-pad. 3. This figure reflects the current die thickness. Please contact Nuvoton as this thickness may change in the future. Jun 28, 2021 Page 75 of 85 Rev1.6 ISD5100 ISD5116 Pad Coordinates (with respect to die center in µm) Pad Pad Name X Axis Y Axis VSSA Analog Ground 1879.45 3848.65 RAC Row Address Clock 1536.20 3848.65 INT Interrupt 787.40 3848.65 XCLK External Clock Input 475.60 3848.65 VCCD Digital Supply Voltage 288.60 3848.65 VCCD Digital Supply Voltage 73.20 3848.65 SCL Serial Clock Line -201.40 3848.65 Address 1 -560.90 3848.65 Serial Data Address -818.20 3848.65 Address 0 -1369.40 3848.65 VSSD Digital Ground -1671.30 3848.65 VSSD Digital Ground -1842.90 3848.65 VSSA Analog Ground -1948.00 -3841.60 MIC+ Non-inverting Microphone Input -1742.20 -3841.60 MIC- Inverting Microphone Input -1509.70 -3841.60 ANA OUT+ Non-inverting Analog Output -1248.00 -3841.60 ANA OUT- Inverting Analog Output -913.80 -3841.60 AGC/AutoMute Cap -626.50 -3841.60 SP- Speaker Negative -130.70 -3841.60 VSSA Analog Ground 202.90 -3841.60 VSSA Analog Ground 292.90 -3841.60 SP+ Speaker Positive 626.50 -3841.60 VCCA Analog Supply Voltage 960.10 -3841.60 VCCA Analog Supply Voltage 1050.10 -3841.60 ANA IN Analog Input 1257.40 -3841.60 AUX IN Auxiliary Input 1523.00 -3841.60 Auxiliary Output 1767.20 -3841.60 A1 SDA A0 ACAP AUX OUT Jun 28, 2021 Page 76 of 85 Rev1.6 ISD5100 11.4. ISD5108 DIE INFORMATION VSSD VSSD INT SDA SCL VCCD A1 VCCD XCLK A0 RAC VSSA ISD5108 Device Die Dimensions (include scribe line) X: 4230 µm Y: 6090 µm Die Thickness [3] ≈ 292.1 µm ± 12.7 µm Pad Opening Single pad: 90 x 90 µm Double pad: 180 x 90 µm VSSA MIC + ISD5108 MIC ANA OUT SP ANA OUT + ACAP VSSA [2] ≈ VCCA [2] SP + ANA IN AUX OUT AUX IN Notes 1. The backside of die is internally connected to Vss. It MUST NOT be connected to any other potential or damage may occur. 2. Double bond recommended, if treated as single doubled-pad. 3. This figure reflects the current die thickness. Please contact Nuvoton as this thickness may change in the future. Jun 28, 2021 Page 77 of 85 Rev1.6 ISD5100 ISD5108 Pad Coordinates (with respect to die center in µm) Pad Pad Name X Axis Y Axis VSSA Analog Ground 1882.40 2820.65 RAC Row Address Clock 1539.15 2820.65 Interrupt 790.35 2820.65 XCLK External Clock Input 478.55 2820.65 VCCD Digital Supply Voltage 291.55 2820.65 VCCD Digital Supply Voltage 76.15 2820.65 SCL Serial Clock Line -198.45 2820.65 Address 1 -557.95 2820.65 Serial Data Address -815.25 2820.65 Address 0 -1366.45 2820.65 VSSD Digital Ground -1668.35 2820.65 VSSD Digital Ground -1839.95 2820.65 VSSA Analog Ground -1945.05 -2821.60 MIC+ Non-inverting Microphone Input -1739.25 -2821.60 MIC- Inverting Microphone Input -1506.75 -2821.60 ANA OUT+ Non-inverting Analog Output -1245.05 -2821.60 ANA OUT- Inverting Analog Output -910.85 -2821.60 AGC/AutoMute Cap -623.55 -2821.60 SP- Speaker Negative -127.75 -2821.60 VSSA Analog Ground 205.85 -2821.60 VSSA Analog Ground 295.85 -2821.60 SP+ Speaker Positive 629.45 -2821.60 VCCA Analog Supply Voltage 963.05 -2821.60 VCCA Analog Supply Voltage 1053.05 -2821.60 ANA IN Analog Input 1260.35 -2821.60 AUX IN Auxiliary Input 1525.95 -2821.60 Auxiliary Output 1770.15 -2821.60 INT A1 SDA A0 ACAP AUX OUT Jun 28, 2021 Page 78 of 85 Rev1.6 ISD5100 11.5. ISD5104 DIE INFORMATION VSSD VSSD VCCD SDA SCL INT A1 VCCD XCLK A0 RAC VSSA ISD5104 Device Die Dimensions (include scribe line) X: 4230 µm Y: 5046 µm ≈ Die Thickness [3] ≈ ISD5104 292.1 µm ± 12.7 µm Pad Opening Single pad: 90 x 90 µm Double pad: 180 x 90 µm VSSA MIC + ANA OUT MIC SP ANA OUT + ACAP VSSA [2] VCCA [2] SP + ANA IN AUX OUT AUX IN Notes 1. The backside of die is internally connected to Vss. It MUST NOT be connected to any other potential or damage may occur. 2. Double bond recommended, if treated as single doubled-pad. 3. This figure reflects the current die thickness. Please contact Nuvoton as this thickness may change in the future. Jun 28, 2021 Page 79 of 85 Rev1.6 ISD5100 ISD5104 Pad Coordinates (with respect to die center in µm) Pad Pad Name X Axis Y Axis VSSA Analog Ground 1882.4 2306.65 RAC Row Address Clock 1539.15 2306.65 INT Interrupt 790.35 2306.65 XCLK External Clock Input 478.55 2306.65 VCCD Digital Supply Voltage 291.55 2306.65 VCCD Digital Supply Voltage 76.15 2306.65 SCL Serial Clock Line -198.45 2306.65 Address 1 -557.95 2306.65 Serial Data Address -815.25 2306.65 Address 0 -1366.45 2306.65 VSSD Digital Ground -1839.95 2306.65 VSSD Digital Ground -1668.35 2306.65 VSSA Analog Ground -1945.05 -2311.60 MIC+ Non-inverting Microphone Input -1739.25 -2311.60 MIC- Inverting Microphone Input -1506.75 -2311.60 ANA OUT+ Non-inverting Analog Output -1245.05 -2311.60 ANA OUT- Inverting Analog Output -910.85 -2311.60 AGC/AutoMute Cap -623.55 -2311.60 SP- Speaker Negative -127.75 -2311.60 VSSA Analog Ground 205.85 -2311.60 VSSA Analog Ground 295.85 -2311.60 SP+ Speaker Positive 629.45 -2311.60 VCCA Analog Supply Voltage 963.05 -2311.60 VCCA Analog Supply Voltage 1053.05 -2311.60 ANA IN Analog Input 1260.35 -2311.60 AUX IN Auxiliary Input 1525.95 -2311.60 Auxiliary Output 1770.15 -2311.60 A1 SDA A0 ACAP AUX OUT Jun 28, 2021 Page 80 of 85 Rev1.6 ISD5100 11.6. ISD5102 DIE INFORMATION VSSD VSSD VCCD SDA SCL INT A1 XCLK VCCD A0 RAC VSSA ISD5102 Device Die Dimensions (include scribe line) X: 4230 µm Y: 5046 µm ≈ Die Thickness [3] ≈ ISD5102 292.1 µm ± 12.7 µm Pad Opening Single pad: 90 x 90 µm Double pad: 180 x 90 µm VSSA MIC + MIC ANA OUT SP ANA OUT + ACAP VSSA [2] VCCA [2] SP + ANA IN AUX OUT AUX IN Notes 1. The backside of die is internally connected to Vss. It MUST NOT be connected to any other potential or damage may occur. 2. Double bond recommended, if treated as single doubled-pad. 3. This figure reflects the current die thickness. Please contact Nuvoton as this thickness may change in the future. Jun 28, 2021 Page 81 of 85 Rev1.6 ISD5100 ISD5102 Pad Coordinates (with respect to die center in µm) Pad Pad Name X Axis Y Axis VSSA Analog Ground 1882.4 2306.65 RAC Row Address Clock 1539.15 2306.65 INT Interrupt 790.35 2306.65 XCLK External Clock Input 478.55 2306.65 VCCD Digital Supply Voltage 291.55 2306.65 VCCD Digital Supply Voltage 76.15 2306.65 SCL Serial Clock Line -198.45 2306.65 Address 1 -557.95 2306.65 Serial Data Address -815.25 2306.65 Address 0 -1366.45 2306.65 VSSD Digital Ground -1839.95 2306.65 VSSD Digital Ground -1668.35 2306.65 VSSA Analog Ground -1945.05 -2311.60 MIC+ Non-inverting Microphone Input -1739.25 -2311.60 MIC- Inverting Microphone Input -1506.75 -2311.60 ANA OUT+ Non-inverting Analog Output -1245.05 -2311.60 ANA OUT- Inverting Analog Output -910.85 -2311.60 AGC/AutoMute Cap -623.55 -2311.60 SP- Speaker Negative -127.75 -2311.60 VSSA Analog Ground 205.85 -2311.60 VSSA Analog Ground 295.85 -2311.60 SP+ Speaker Positive 629.45 -2311.60 VCCA Analog Supply Voltage 963.05 -2311.60 VCCA Analog Supply Voltage 1053.05 -2311.60 ANA IN Analog Input 1260.35 -2311.60 AUX IN Auxiliary Input 1525.95 -2311.60 Auxiliary Output 1770.15 -2311.60 A1 SDA A0 ACAP AUX OUT Jun 28, 2021 Page 82 of 85 Rev1.6 ISD5100 12. ORDERING INFORMATION Jun 28, 2021 Page 83 of 85 Rev1.6 ISD5100 13. REVISION HISTORY VERSION DATE 1.0 Jul, 2004 Vcc: Industrial temp: 2.7 – 3.3V (5108: 2.7- 3.6V) Section 7.3.10 CFG0: Select 8Ω speaker output Section 7.6.2 AuxOut: Correct parameter name to OPA1 Application diagram: Revise pin # on SDA & A1 1.1 Nov, 2004 1.2 Apr, 2005 1.3 Oct, 2005 Revise Operating conditions sections Add Pb-free option to Ordering Info Revise Ordering Info section Update disclaim section Revise Packaging information. 1.4 May, 2007 1.5 May 21, 2020 1.6 Jun 28, 2021 Jun 28, 2021 DESCRIPTION Remove leaded package offer Update XCLK description Revise application diagram Change logo Update Document Format Remote TSOP Package Update Ordering Information Page 84 of 85 Rev1.6 ISD5100 Important Notice Nuvoton Products are neither intended nor warranted for usage in systems or equipment, any malfunction or failure of which may cause loss of human life, bodily injury or severe property damage. Such applications are deemed, “Insecure Usage”. Insecure usage includes, but is not limited to: equipment for surgical implementation, atomic energy control instruments, airplane or spaceship instruments, the control or operation of dynamic, brake or safety systems designed for vehicular use, traffic signal instruments, all types of safety devices, and other applications intended to support or sustain life. All Insecure Usage shall be made at customer’s risk, and in the event that third parties lay claims to Nuvoton as a result of customer’s Insecure Usage, customer shall indemnify the damages and liabilities thus incurred by Nuvoton. Jun 28, 2021 Page 85 of 85 Rev1.6
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