Source: http://www.google.com/patents/US5877975?dq=3798359
Timestamp: 2017-05-25 20:56:00
Document Index: 234474827

Matched Legal Cases: ['art 1', 'art 2', 'art 3', 'art 1', 'art 2', 'art 1', 'art 2', 'art 3', 'art 3']

Patent US5877975 - Insertable/removable digital memory apparatus and methods of operation thereof - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inPatentsEach device of a family of removable digital media devices (310, 320, 330, 340, 350 and 360) may be plugged into a host to permits the host to store data in it or to retrieve data from it. The form factors of the digital media devices in the family and the connector system used by the digital media devices...http://www.google.com/patents/US5877975?utm_source=gb-gplus-sharePatent US5877975 - Insertable/removable digital memory apparatus and methods of operation thereofAdvanced Patent SearchTry the new Google Patents, with machine-classified Google Scholar results, and Japanese and South Korean patents.Publication numberUS5877975 APublication typeGrantApplication numberUS 08/689,687Publication dateMar 2, 1999Filing dateAug 13, 1996Priority dateAug 13, 1996Fee statusPaidPublication number08689687, 689687, US 5877975 A, US 5877975A, US-A-5877975, US5877975 A, US5877975AInventorsRobin J. Jigour, David K. WongOriginal AssigneeNexcom Technology, Inc.Export CitationBiBTeX, EndNote, RefManPatent Citations (12), Non-Patent Citations (21), Referenced by (206), Classifications (16), Legal Events (7) External Links: USPTO, USPTO Assignment, EspacenetInsertable/removable digital memory apparatus and methods of operation thereof
US 5877975 AAbstract
Each device of a family of removable digital media devices (310, 320, 330, 340, 350 and 360) may be plugged into a host to permits the host to store data in it or to retrieve data from it. The form factors of the digital media devices in the family and the connector system used by the digital media devices are compact for minimizing the volume of space occupied in portable devices and for easy storage. Some embodiments (310, 320, 330, 350 and 360) provide an elongated compact form factor that provides easy and firm grasping for insertion and removal. The digital media devices of the family have respective body portions (312, 322, 332, 342, 352 and 362) preferably of a rigid or semi-rigid material. Preferably, the digital media devices of the family use serial memory requiring few power and signal lines, so that few electrical contacts are required. In particular, a small number of durable contact pads form the contact arrays (314, 324, 334, 344, 354 and 364) on the digital media devices, which in conjunction with corresponding contact pads mounted into a suitable socket provide for easy and convenient insertion and removal and for robust and reliable electrical contact over a long insertion lifetime. Preferably, the digital media devices of the family incorporate flash memory, which permits low voltage operation, low power consumption, and high capacity non-volatile data storage. Preferably, the digital media devices of the family are fabricated using surface mount techniques (310 and 320) or particularly inexpensive "Chip on Board" techniques (330, 340, 350 and 360).
1. A storage apparatus comprising:a body of an elongated shape having first and second ends, a first substantially constant width portion proximate the first end, and first and second opposing major surfaces; an array of electrical contact pads integral with the body and disposed generally level with the first major surface and extending substantially across the substantially constant width portion proximate the first end of the body, the electrical contact pad array including a data pad, a power pad, a ground pad, and a clock pad; a serial data line integral with the body and coupled to the data pad; a power line integral with the body and coupled to the power pad; a ground line integral with the body and coupled to the ground pad; a clock line integral with the body and coupled to the clock pad; and a high density memory integrated circuit integral with the body, the memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line; wherein the body further comprises a portion extending from the first substantially constant width portion and terminating in the second end, the extending portion being generally larger than the first substantially constant width portion for convenient grasping with the forefinger and thumb of the human hand. 2. An apparatus as in claim 1 wherein the body is key-shaped.
3. A storage apparatus comprising:a generally rectangular elongated body having first and second substantially planar opposing major surfaces and first and second ends and comprising a main portion and a substrate portion; an array of electrical contact pads integral with the body and disposed generally in the plane of the first major surface and extending substantially across a portion of the first major surface proximate the first end, the electrical contact pad array including a data pad, a power pad, a ground pad, and a clock pad, the electrical contact pad array further being disposed on a second side of the substrate portion opposing the first side and substantially coplanar with the first major surface; a serial data line integral with the body and coupled to the data pad; a power line integral with the body and coupled to the power pad; a ground line integral with the body and coupled to the ground pad; a clock line integral with the body and coupled to the clock pad; a high density memory integrated circuit integral with the body, the memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line, and the memory integrated circuit being disposed on a first side of the substrate portion and in a cavity of the main body portion; and an additional memory integrated circuit disposed on the first side of the substrate portion and in the cavity of the main body portion, the additional memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line. 4. A storage apparatus comprising:a generally rectangular elongated body having first and second substantially planar opposing major surfaces and first and second ends; an array of electrical contact pads integral with the body and disposed generally in the plane of the first major surface and extending substantially across a portion of the first major surface proximate the first end, the electrical contact pad array including a data pad, a power pad, a ground pad, and a clock pad; a serial data line integral with the body and coupled to the data pad; a power line integral with the body and coupled to the power pad; a ground line integral with the body and coupled to the ground pad; a clock line integral with the body and coupled to the clock pad; a high density memory integrated circuit integral with the body, the memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line, and the memory integrated circuit being disposed on the first major surface; and an additional memory integrated circuit disposed on the second major surface, the additional memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line. 5. A storage apparatus comprising:a generally rectangular elongated body having first and second substantially planar opposing major surfaces and first and second ends, the body being about 15 mm wide, from about 54 to 25 MM long, and about 0.8 mm thick; an array of electrical contact pads integral with the body and disposed generally in the plane of the first major surface and extending substantially across a portion of the first major surface proximate the first end, the electrical contact pad array including a data pad, a power pad, a ground pad, and a clock pad; a serial data line integral with the body and coupled to the data pad; a power line integral with the body and coupled to the power pad; a ground line integral with the body and coupled to the ground pad; a clock line integral with the body and coupled to the clock pad; and a high density memory integrated circuit integral with the body, the memory integrated circuit having a serial data port coupled to the serial line, a power node coupled to the power line, a ground node coupled to the ground line, and a clock node coupled to the clock line. 6. A method for detecting endwise insertion of a card into a socket, comprising:arrange a ground pad and a card detect pad on the card generally in the direction of insertion of the card into the socket; activate a detect control signal coupled to the card detect pad through a resistive element; monitor the card detect pad to determine whether the active detect control signal is asserted on the card detect pad and attempt to perform a card read operation, wherein:if the active detect control signal is present on the card detect pad and the read operation is successful, the card is properly inserted and is not write protected; if the active detect control signal is present on the card detect pad and the read operation is not successful, the card is not inserted; if the active detect control signal is not present on the card detect pad and the read operation is successful, the card is properly inserted and is write protected; and if the active detect control signal is not present on the card detect pad and the read operation is not successful, the card is not properly inserted. 7. A method for protecting electronic circuits during edgewise removal of a card from a socket, comprising:arrange a ground pad and a card detect pad on the card generally in the direction of insertion of the card into the socket; activate a detect control signal coupled to the card detect pad through a resistive element; monitor the card detect pad to determine whether the active detect control signal is asserted, wherein a substantial period of active detect control signal on the card detect pad followed by a substantial period of inactive detect control signal on the card detect pad is indicative of card removal; and power down circuits coupled to the card when card removal is indicated. Description
FIG. 1 shows to scale the surface area of a number of high capacity memory cards types presently available. The surface area of a flash PC card is shown at 100 in FIG. 1. Flash PC cards are compliant with the Personal Computer Memory Card International Association ("PCMCIA") standard, which specifies a form factor of approximately 85.6 mm (3.37 inches) by 54 mm (2.126 inches), with a thickness of either about 3 mm for a Type-I card or about 5 mm for a Type-II card. The connector specified by the PCMCIA standard uses 66 pins organized in two rows of 33 pins each with 1.27 mm (50 mils) spacing between pins. The physical specifications for PC cards are described in a publication of the Personal Computer Memory Card International Association/JEIDA entitled PC Card Standard, Volume 3: Physical Specification, Document No. 0295-03-1500, February 1995.
Flash PC cards typically have a high memory capacity of from about 2 Megabytes to 85 Megabytes, although recently even higher capacity cards have been introduced. Like hard-disks, flash PC cards spend about 75 percent of operation time being read from and 25 percent being written to. The two primary PC card interface types are ATA and Linear. PC cards that supports the ATA interface use an on-card ATA controller, which allows "plug and play" compatibility between portable computers and PDAs. Linear flash cards do not use a dedicated ATA controller and require software drivers to implement file interface protocol.
While flash PC cards can provide sufficient amounts of memory for a broad range of applications, they have not been widely accepted for use in applications such as mobile and portable electronics, or for use in applications having significant cost sensitivity. PC cards simply tend to be too large for many portable applications such as pagers, voice recorders, mobile telephones, and hand-held meters. PC cards are also too bulky and heavy for carrying in a pocket or wallet, as would be desirable for many consumer applications. Current PC cards are also quite expensive, hence are offered generally as after market enhancements or add-ons. PC cards can be made available at extremely high memory capacities because of improved memory technology; however, such extremely high memory capacities are in excess of what is optimal for many mobile and portable applications. Moreover, although the insertion lifetime of 68-pin PC card connectors, which is about 10,000 cycles, is generally adequate for portable computers and PDAs, it is inadequate for other applications involving more frequent insertion and removal of the storage media than encountered in portable computing. In addition, the high number of pins and the tendency of the narrow deep sockets on the PC cards to collect foreign material increase the probability of failure, especially if the PC cards are not carefully handled. Also, PC cards have parallel busses, which are problematical since they permit multiple signal transitions that cause system noise and interference with wireless RF products. Some PC cards commonly available use channel hot electron flash technology, which because of its inherent high current demands tends to make erase/write programming times lengthy and reduce effective battery lifetimes in mobile and portable applications.
The compact flash card is a small format flash memory card that was initially announced by SanDisk Corporation in 1994. The form factor of the compact flash card is 36×43×3.3 mm, and the surface area thereof, which is shown at 110 in FIG. 1, is approximately 1/3 the surface area of the standard PC Card. The card has a 50 pin connector that is a subset of the PC card interface. The card supports the IDE/ATA interface standard by means of an on-card ATA controller IC. Memory capacity in the range of 2 Megabytes to 15 Megabytes is currently available, although greater memory capacity devices are likely to be introduced. Both 5 volt and 3.3 volt power supplies are supported. A compact flash card is interfaced to notebook computers and PDAs by inserting the card into a special PC card adapter. The compact flash series is described in a publication of the SanDisk Corporation entitled Compact flash Series Preliminary Data Sheet, Document No. 80-11-00015, Rev. 1.0, October 1994.
The miniature card is a small format card that was initially announced by Intel Corporation in 1995. The form factor of the miniature card is 35×33×3.5 mm, and the surface area, which is shown at 120 in FIG. 1, is approximately 25% the surface area of the standard PC card. The miniature card has a 60 pin Elastimeric connector rated at a minimum insertion lifetime of 5,000 cycles. The card supports a linear addressing range of up to 64 Megabytes of memory using a 16-bit data bus. Memory capacity in the range of 2 Megabytes to 4 Megabytes is currently available, although greater memory capacity devices are likely to be introduced. The miniature card specification allows for flash, DRAM and ROM memory types. Both 5 volt and 3.3 volt power supplies are supported by the specification. A miniature card is interfaced to notebook computers and PDAs that support the standard PC card interface with a special PC card adapter. A miniature card specification is described in Miniature Card Specification, Release 1.0, February 1996, available from Intel Corporation of Santa Clara, Calif.
The solid state floppy disk card, or SSFDC, is a small format card initially announced by Toshiba Corporation in 1995. The form factor of the SSFDC card is 45×37×0.76 mm, and the surface area thereof, which is shown at 120 in FIG. 1, is approximately 36% the surface area of the standard PC card. The SSFDC has 22 flat contact pads, some of which are I/O pads for both address and data input and output as well as for command inputs. The card specification is dedicated to byte serial NAND-type flash memory. Memory capacity of 2 Megabytes is currently available, although memory capacity in the range of 512 kilobytes to 8 Megabytes is anticipated. The specification accommodates 5 volt or 3.3 volt power supplies. An SSFDC is interfaced to notebook computers and PDAs that have the standard PC card interface with a special PC card adapter. An illustrative device is type TC5816ADC, which is described in Preliminary TC5816ADC Data Sheet No. NV16030496, April 1996, available from Toshiba America Electronic Components, Inc. of Irvine, Calif. The device is said to be suitable for such applications as solid state file storage, voice recording, image file memory for still cameras, and other systems which require high capacity, non-volatile memory data storage.
Seimens Components of Cupertino, Calif. has described a device known as MultiMediaCards, or MMC; see Portable Design, July 1996, p. 23 et seq. The form factor of the MMC package is 37×45×1.4 mm, and the surface area, which is shown at 140 in FIG. 1, is approximately 36% that of the standard PC card. The MMC package has 6 edge-mounted contact pads with an insertion lifetime of 10,000 cycles, and uses a serial bus. Initially, MCCs are expected to be offered with a choice of 16 Megabit or 64 Megabit ROM memory, but is reported to be teaming up with undisclosed partners to put flash memory on its MMC cards. The specification accommodates a 3.3 volt power supply. The device is said to be suitable for such applications as video games, talking toys, automobile diagnostics, smart phones (tailored operating systems or special programs), PDAs (tailored operating systems or special programs), and notebooks through a PDA adapter.
The Integrated Circuit (IC) card format and the similar Identification (ID) card format, commonly known as smart cards, were introduced in the mid 1980's, and have been standardized by the International Organization for Standardization (ISO); see International Organization for Standardization, Identification Cards--Integrated Circuit Cards with Contacts, Part 1: Physical Characteristics, Document No. ISO 7816-1, July 1987; International Organization for Standardization, Identification Cards--Integrated Circuit Cards with Contacts, Part 2: Dimensions and Location of Contacts, Document No. ISO 7816-2, May 1988; and International Organization for Standardization, Identification Cards--Integrated Circuit Cards with Contacts, Part 3: Electronic Signals and Transmission Protocols, Document No. ISO 7816-3, September 1989. Smart cards are credit card sized and typically contain a microcontroller with a small amount of EEPROM memory, typically 256 to 8K bits. The surface area of the smart card is shown at 210 in FIG. 2. The length and width of the smart card is nearly identical with the length and width of the PC card, but the smart card is much thinner. The cards are popular in Europe are making inroads into the US market. Primary applications are smart telephone calling cards and stored value cards, the later application being promoted by credit card companies like Visa and Master card as a replacement for paper currency. IC and ID cards have a simple contact pattern of eight flat contact pads pins designated C1-C8 of which only six are used. Contact signal assignments are C1=Vcc (supply voltage), C2=RST (reset), C3=CLK (clock signal), C4=Reserved, C5=GND (ground), C6=Vpp (programming voltage), C7=I/O (data input/output) and C8=Reserved. Due to their popularity in Europe, a great infrastructure of connectors and readers is already established for IC and ID cards.
Another low memory capacity card format is known as the Subscriber Identification Module ("SIM"), which is used in conjunction with mobile telephones based on the Global System for Mobile Communications ("GSM") standard. The SIM specification is set forth in a publication of the European Telecommunication Standard Institute entitled European Digital Cellular Telecommunication System, Global System for Mobile Communications, Phase 2: Specification of Subscriber Identity Module--Mobile Equipment Interface, Document No. GSM11.11, Reference (RE/SMG)-091111PR3, ICS 33.060.50, December 1995. The form factor of the SIM is 25 mm×15 mm×0.76 mm, and the surface area thereof, which is shown at 220 in FIG. 2, is much smaller than the standard PC card. SIMs offer only a very limited amount of memory, typically less than one kilobit. However, this small amount of memory is sufficient to provide a GSM mobile phone with secure identification of the GSM subscriber, and may also hold a small amount of data for call metering, phone number storage, and in some cases very short data messages (less than a few hundred bytes of data). The SIM uses the same 8 pad contact pattern as the IC card, but only five of the pads are required for Vcc, RST, CLK, GND, and I/O. The plug-in SIM typically is housed in a small hinged smart card connector similar to the type CCM03 available from ITT Cannon Corporation of Santa Ana, Calif. The small form factor allows the GSM SIM to be placed inside the phone as a plug-in module. Because the GSM SIM typically is removed only if a different GSM phone is to be used, GSM SIM connectors typically are designed for fewer insertion/removal cycles than normally experienced with IC and ID cards.
The various embodiments of the present invention have many advantages. The memory capacity of some of the embodiments is ideally suited to the storage and transfer large amounts of digital information such as commonly encountered in audio, data and image applications and the small yet convenient form factors make them ideally suited to personal, mobile and portable electronics equipment. Some of the embodiments of the present invention are rugged and durable enough to withstand numerous insertion/removal cycles. Some of the embodiments of the present invention are compatible with existing standards, some are inexpensive to interface to, and some are particularly inexpensive to manufacture.
One embodiment of the present invention, a storage apparatus for digital media applications, comprises a body, an array of electrical contact pads disposed generally level with a first major surface of the body, a data line, a power line, a ground line, a clock line, and a high density memory integrated circuit. The memory integrated circuit is coupled to the electrical contact pad array by the data line, the power line, the ground line, and the clock line.
FIGS. 11 and 12 are block schematic diagrams of signal and power connections for two exemplary interfaces for digital media devices of the FIG. 3 family;
FIG. 13 is a cross-sectional view of a surface mount digital media device having two surface-mounted packaged integrated circuits;
FIG. 14 is a cross-sectional view of a chip-on-board-modular digital media device having one chip;
FIG. 15 is a cross-sectional view of a chip-on-board-modular digital media device having two chips;
FIG. 16 is a cross-sectional view of a chip-on-board-direct digital media device having two chips; and
FIGS. 17-21 are pictorial views of various applications for the digital media devices in the FIG. 3 family.
Digital media means insertable/removable memory media for storing and transferring large digital files, especially audio, data and image files, in personal, portable and mobile environments. Digital media storage involves a higher percentage of erase/write accesses than code storage and ordinary data and mass storage, typically about 50 percent read and 50 percent erase/write ratio. The storage requirement typically is high capacity, i.e. about one Megabit or greater. For example, a one Megabit flash device might store 1-2 minutes of digital voice recording, a 10 page fax, or 10-20 medium resolution compressed digital camera pictures. Preferably, digital media supports read, erase, and write at either 5 volt or 3 volt supply levels, and contains small sectors that can be programmed quickly to efficiently use battery-power and to keep pace with high-speed portable and mobile applications. Examples of media elements stored or transferred include voice and sound clips, facsimile, pictures, writing, drawing, scanned images, maps, e-mail, data logging, downloadable code, and general data files. A few examples of emerging digital media storage applications include digital cameras, solid-state voice recorders, portable scanners and bar-code readers, voice/data pagers, cellular phone answering machines, portable pen-based tablets, hand-held terminals and meters, and portable data acquisition equipment.
Although generally shown as having a rectangular shape, the digital media devices of the family 300 may be made in other shapes. For example, the digital media device 350 has a key-like shape which provides not only convenient handling but also more surface area for additional memory circuits and for the manufacturer's logo, use instructions, user written notes, and the like.
FIG. 4 shows illustrative surface area profiles 410, 420 and 430 of various digital media devices, which are at the same scale as the various surface area profiles shown in FIGS. 1 and 2. As will be appreciated by comparing the surface area profiles 410, 420 and 430 with the various surface are profiles for flash memory devices shown in FIG. 1, the digital media devices having the surface area profiles 410, 420 and 430 have numerous advantages, even while providing memory capacity that is comparable with most other high capacity cards, and comparable even with PC cards at the low end of their typical capacity range, yet ideally suited to digital media storage applications. For example, the surface area profile 420 is only about 15% the surface area profile 100 of the PCMCIA form factor and has a relatively small insertion volume requirement, and even the profile 410 is only about 18% the surface area profile 100 of the PCMCIA form factor and also has a relatively small insertion volume requirement. Compare the surface area profiles 410 and 420 with, for example, the surface area profile 110 of the compact flash form factor, the surface area profile 120 of the miniature card form factor, and the surface area profile 130 of the SSFDC form factor. The compact flash surface area profile 110 is about 33% the surface area profile 100 of the PCMCIA form factor and has a relatively large insertion volume requirement. The miniature card surface area profile 120 is about 25% the surface area profile 100 of the PCMCIA form factor and has a relatively moderate insertion volume requirement. The SSFDC surface area profile 130 is about 36% the surface area profile 100 of the PCMCIA form factor and has a relative large insertion volume requirement.
The long form factor 420 shown in FIG. 4 has a width of 15 mm, a length of 45 mm, and a thickness of 0.76 mm. Long form factor 410, which is compatible with smart card manufacturing techniques because its length is the same as the width of a smart card, has a width of 15 mm, a length of 54 mm, and a thickness of 0.76 mm. The short form factor 430 shown in FIG. 4 has a width of 15 mm, a length of 25 mm, and a thickness of 0.76 mm. The long and short form factor dimensions are illustrative, and the optimal size of the form factors suitable for the digital media device family 300 is influenced by several factors, including, for example, the size of the host, the size of the electrical contact array required, the need for sufficient body surface and a suitable shape for a user to grasp the device for insertion, removal, and transport, convenience of transport and storage, and compatibility for insertion into compartments such as battery compartments commonly provided in personal, portable and mobile equipment. The choice of form factor within the range of acceptable form factors is also influenced by other factors, including, for example, whether sufficient surface on the body is required for a user to grasp the digital media device for insertion and removal without touching the electrical contact array, which tends to favor a longer form factor; and whether the digital media device is intended for cost-sensitive applications, in which case the availability of low cost high volume manufacturing techniques is important. An example of the latter is a digital media device having a length equal to the width of a standard ISO smart IC card, which permits manufacturing equipment suitable for standard ISO smart cards to be used in the manufacture of the digital media device. The thickness of the digital media devices in the family 300 preferably achieves sufficient rigidity to permit good control over insertion and removal, and to prevent damage to the integrated circuit due to device stress under normal use. The rigidity requirements may be relaxed where the die is small or is otherwise protected, as where the die is mounted using COB packaging techniques in which the die is mounted on a rigid substrate and encased with epoxy material. Illustratively, where the media device is made from PVC, PVCA, or FR4 epoxy glass, a convenient thickness is about 0.8 mm.
Digital media devices based on the ISO IC card standard are shown in FIGS. 5, 6 and 7. Illustratively, the digital media device 500 of FIG. 5 is 15 mm wide and 45 mm long. The contact pad array 510 is set back from the head of the digital media device 500 by 3.0 mm, and from the side of the digital media device 500 by 2.5 mm. Each of the contact pads 511, 512, 513, 514, 515, 516, 517 and 518 is 2.25 mm by 4.0 mm in size. Typically, gaps between adjacent contact pads 511 and 512, 512 and 513, 513 and 514, 515 and 516, 516 and 517, and 517 and 518 are about 0.33 mm, while pads 511 and 515, 512 and 516, 513 and 517, and 514 and 518 are about 3.5 mm. The contact pads 511-518 are made of any suitable contact pad material, such material being well known in the art.
Illustratively, the digital media device 600 of FIG. 6 is 15 mm wide and 45 mm long. The contact pad array 610 is set back from the head of the digital media device 600 by 3.0 mm, and from the side of the digital media device 600 by 2.5 mm. Each of the contact pads 611, 612, 613, 614, 616, 617 and 618 is 2.25 mm by 4.0 mm in size. The contact pad 615 has a portion that is 2.25 mm by 4.0 mm in size, but also has a first extension portion that extends about 3.5 mm toward contact pad 611, and a second extension portion that is just less than 3.5 mm wide and lies between pads 612 and 616, pads 613 and 617, and pads 614 and 618, which are spaced 3.5 mm from one another. Typically, gaps between adjacent portions of the contact pads 611-618 are about 0.33 mm. The contact pads 611-618 are made of any suitable contact pad material, such material being well known in the art.
Illustratively, the digital media device 700 of FIG. 7 is 15 mm wide and 45 mm long. The contact pad array 710 is set back from the head of the digital media device 700 by 3.0 mm, and from the sides of the digital media device 700 by 2.5 mm. Each of the contact pads 711, 712, 713, 714, 717 and 718 is 2.25 mm by 4.0 mm in size. The contact pad 715 also has a portion that is 2.25 mm by 4.0 mm in size, but has a first extension portion that extends about 3.5 mm toward contact pad 711, and a second extension portion that is 1.75 mm wide and lies between pads 712 and 716. Pads 713 and 717 and pads 714 and 718 are spaced 3.5 mm from one another, and pads 712 and 716 are spaced 4.5 mm from one another. Typically, gaps between adjacent portions of the contact pads 711-718 are about 0.33 mm wide, although the edge of the pad 716 toward the head of the digital media device 700 is spaced 2.75 mm from the second extension portion of the pad 715. The contact pads 711-718 are made of any suitable contact pad material, such material being well known in the art.
The socket shown in FIG. 8, FIG. 9 and FIG. 10 is illustrative, and suitable sockets for receiving the digital media device 1000 are readily available. For example, standard sockets conforming to the eight pin ISO IC card standard are suitable if modified to guide the relatively narrower digital media device 1000 into engagement with the electrical contacts of the socket. The ISO IC sockets are available from various manufacturers, including ITT Cannon Corporation of Santa Ana, Calif.; see CCM Smart Card Connectors Catalog, Document No. CCM 7/94-A, July 1994. The six pad SIM sockets are also suitable for receiving the digital media device 1000 where only six contact pads are active, provided they are modified by removal of a siderail to permit side insertion. Six pad SIM sockets and custom eight pad SIM sockets are available from various manufacturers, including Amphenol of Hamden, Conn.
Preferably, the digital media devices of the family 300 incorporate high density serial flash memory, which requires few power and signal lines and permits low voltage operation, low power consumption, and high capacity non-volatile data storage. A suitable serial flash memory circuit is disclosed in U.S. Pat. No. 5,291,584, issued Mar. 1, 1994 to Challa et al. and entitled "Method and Apparatus for Hard Disk Emulation," which is hereby incorporated herein by reference in its entirety. Other serial standards and specifications may also be suitable other than the specification set forth in the aforementioned Challa et al. patent, including, for example, SPI, I2C, COPS and MICROWIRE. However, serial flash memory of the type disclosed in the aforementioned Challa et al. patent is particularly advantageous because it requires a minimum number of electrical contacts, is capable of being manufactured at high memory densities, is of relatively small die size, and has low power consumption. For example, the Challa bit-serial flash memory requires only four outside connections, viz. Vcc, ground, data input/output ("I/O"), and clock. Other connections may be desirable in some applications or for other types of flash memory, including, for example, chip select, write protect, ready/busy, and memory test. Typical densities available with current process technology are in the range of 1 Megabit to 16 Megabits, and densities are expected to increase with improvements in process technology. A memory density of, for example, 8 Megabits fabricated with conventional 0.7 μm process technology typically is presently available.
The contact pads of the digital media devices in the family 300 are assigned signal and power functions depending on the interface selected. Preferred serial interface protocols are the Nexcom Serial Interface protocol, or NXS protocol, which is described in the aforementioned Challa et al. patent and specifies a two-wire interface, viz. Clock and Data I/O; and the Serial Peripheral Interface ("SPI") protocol, which specifies a four-wire interface, viz. Clock, Data In, Data Out, and Chip Select. The NXS and SPI protocols are illustrative, and other protocols may be used if desired. While the use of eight contact pads is described, six pads would be entirely satisfactory for some applications and the interface protocols would be adjusted accordingly. Where the NXS protocol is selected, the pad assignments of, for example, the digital media device 700 (pad assignments for the digital media devices 500 and 600 are analogous) are as follows: Vcc at pad 711, NC (no connection) at pad 712, CLK at pad 713, NC at pad 714, GND and DT (card detect) at pad 715 (the digital media device 500 does not support DT), NC/WP and DT at pad 716, DIO at pad 717, and NC at pad 718. Where the SPI interface is selected, the pad assignments of, for example, the digital media device 700 are as follows: Vcc at pad 711, CSO at pad 712, CLK at pad 713, CS1 at pad 714, GND and DT at pad 715 (the digital media device 500 does not support DT), WP and DT at pad 716, SIO at pad 717, and RB (Ready/Busy) at pad 718.
FIG. 11 is a block schematic diagram of illustrative electrical connections suitable for the NXS interface protocol. Vcc and ground are furnished to an NXS protocol digital media device 1110, which includes, illustratively, the contact pad array 710 (contact pad arrays 510 and 610 are analogous) through respective contact pads 711 and 715. The digital media device 1110 includes two NXS protocol memory integrated circuits 1112 and 1114 (alternatively, the digital media device 1110 may contain one memory integrated circuit or more than two memory integrated circuits). A controller 1100, which is any suitable controller, including, for example, general purpose microcontrollers, digital signal processors, and application-specific integrated circuit logic, furnishes its clock signal SCK to the CLK ports of the NXS protocol memory integrated circuits 1112 and 1114 through the contact pad 713, and its data signal SIO to the DIO ports of the NXS protocol memory integrated circuits 1112 and 1114 through the contact pad 717. As further described in the aforementioned Challa et al. patent, the NXS protocol supports multiple memory integrated circuits by having each memory integrated circuit receive chip select address information through the serial terminal, decode the chip select address information using on-board logic, and self-activate when the decoded address matches the IC's static address. The static addresses of the integrated circuits 1112 and 1114 are established by connecting the A0\, A1\, A2\ and A3\ terminals to Vcc and ground, as appropriate. Resistor 1102 is a pull-up resistor having a value of, for example, 10,000 ohms, and is useful in card insertion/removal detection. The resistor 1102 is connected between a detect control port DC and a write protect-card detect port WP-DT of the controller 1100. The write protect-card detect port WP-DT of the controller 1100 contacts pad 716 when the digital media card is inserted into it's socket.
FIG. 12 is a block schematic diagram of illustrative electrical connections suitable for the SPI interface protocol. Vcc and ground are furnished to an SPI protocol digital media device 1210, which includes, illustratively, the contact pad array 710 (contact pad arrays 510 and 610 are analogous) through respective contact pads 711 and 715. The digital media device 1110 includes two SPI protocol memory integrated circuits 1212 and 1214 (alternatively, the digital media device 1210 may contain one memory integrated circuit or more than two memory integrated circuits). A controller 1200, which is any suitable controller, furnishes its clock signal SCK to the SCK ports of the SPI protocol memory integrated circuits 1212 and 1214 through the contact pad 713, and its data signal SIO to the SIO ports of the SPI protocol memory integrated circuits 1212 and 1214 through the contact pad 717. The SPI protocol supports multiple memory integrated circuits by having each memory integrated circuit activated by a specific chip select signal. Hence, memory integrated circuit 1112 is selected by signal CS0 applied through pad 712, and memory integrated circuit 1114 is selected by signal CS1 applied through pad 714. Resistor 1202 is a pull-up resistor having a value of, for example, 10,000 ohms, and is useful in card insertion/removal detection. The resistor 1202 is connected between a detect control port DC and a write protect-card detect port WP-DT of the controller 1200. The write protect-card detect port WP-DT of the controller 1200 contacts pad 716 when the digital media card is inserted into it's socket. A ready-busy port of the controller 1200 is connected to corresponding ports of the memory integrated circuits 1212 and 1214 through pad 718.
Optional write protection is achieved using the GND-DT and WP-DT ports. While the following functional description pertains to the NXS controller 1100 and digital media device 700, the SPI controller 1200 and digital media devices 500 and 600 function in an analogous manner. When write protection is desired, pad 726, which is electrically identical to pad 716, is shorted to pad 725, which is electrically identical to pad 715, using, for example, conductive tape, a conductive edge clip, or an integrated mechanical switch. When the digital media card 700 is inserted into a socket, the WP-DT port of the controller is pulled down, which is sensed as write protect by the controller 1110.
The digital media device 700 supports a card detection function with its unique arrangement of pads in the pad array 710. While the following functional description pertains to the controller 1100, controller 1200 functions in an analogous manner unless otherwise mentioned. The detect control or DC port of the controller 1100 goes high at particular times to interrogate the socket. Illustratively, the DC port is periodically brought high for a brief period. If the card detect port or DT port of the controller 1100 is pulled up, it is an indication that no card is present in the socket or that a properly inserted card is present in the socket and is not write protected. A read is then attempted by sending an read opcode and static address on the port SIO and clocking port SCK (controller 1200 activates the appropriate chip select port, clocks port SCK, and sends a read opcode). If the read is successful, a digital media device is properly installed and a transaction begins. If the read is not successful, no card is present. However, if the DT port is not pulled up, it is an indication that a card is present in the socket but is not properly inserted or that a properly inserted card is present in the socket and is write protected. A read is then attempted. If the read is successful, a write-protected digital media device is properly installed and a transaction begins. If the read is unsuccessful, an improperly inserted card is present and the controller 1100 signals an insertion error.
The digital media device 700 supports a card removal detection function with its unique arrangement of pads in the pad array 710. While the following functional description pertains to the controller 1100 (NXS protocol), controller 1200 (SPI protocol) functions in an entirely analogous manner. As the digital media device 700 is removed from its socket, pad 716 breaks contact with the WP-DT port and the resistor 1102 pulls up the WP-DT port for a relatively large number of clock cycles. This event is detected by the microcontroller 1100. Next, the ground pad 715 makes contact with the WP-DT port and pulls it down for a relatively large number of clock cycles, an event which is also sensed by the microcontroller 1100. The sequence of a prolonged high and low drive of the WP-DT port is interpreted by the microcontroller 1100 as a card removal operation, and the microcontroller 1100 then begins the process of powering down the interface circuits. During the power down operation, pads 717 and 718 break contact with their respective ports, which are protected since they contact only the non-conductive material of the body of the digital media device 700. Power-down is completed before any pads of the digital media device can come into improper contact with pads of the socket, thereby prevent damage to any circuits of the host or the digital media device.
Preferably, the digital media devices of the family 300 are fabricated using surface mount techniques or "Chip on Board" ("COB") techniques. Digital media devices 310 and 320 of FIG. 3 and the digital media device 1300 of FIG. 13 are illustrative of surface mount techniques. COB techniques include a chip-on-board modular technique, of which the digital media devices 330, 340 and 350 of FIG. 3 and the digital media devices 1400 and 1500 of FIGS. 14 and 15 are illustrative, and a chip-on-board direct technique, of which the digital media device 360 of FIG. 3 and the digital media device 1600 of FIG. 16 are illustrative. The COB techniques are advantageous in that they are particularly inexpensive.
FIG. 13 shows in cross-section a digital media device 1300 having two packaged memory integrated circuits mounted using surface mount techniques. It will be appreciated that only a single packaged integrated circuit may be used if desired, or more than two packaged integrated circuits may be used if space permits. A contact pad array 1320, represented by contact pads 1322 and 1326, is fabricated on the body 1310 using well known printed circuit board techniques. The body 1310 is made of any suitable preferably insulate material such as plastic, fiberglass, ceramic, PVC, PVCA, FR4, or any suitable rigid or semi-rigid, non-conductive, and durable material. Packaged integrated circuits 1340 and 1350, which may be packaged in any convenient manner although low profile plastic dual flat pack packaging is preferred, are mounted on opposite sides of the body 1310. Alternatively, packaged integrated circuits 1340 and 1350 may be mounted on the same side of the body 1310 if space allows. A suitable interconnect network is laid out between the packaged integrated circuits 1340 and 1350 and the contact pad array 1320 using well known printed circuit board techniques. A suitable encasing material 1330 is placed about the packaged integrated circuits 1340 and 1350 to provide protection and a gripping surface for manual handling of the digital media device 1300. The encasing material may encase the entire end of the digital media device, as shown by the digital media device 310 (FIG. 3), or may be localized about the packaged integrated circuit chips as shown in FIG. 13 and by the digital media device 320 (FIG. 3) so as to leave the long edges of the digital media device uncovered so that the digital media device 320 may be inserted fully into a slot via edge guides (not shown).
FIG. 14 shows in cross-section a digital media device 1400 having one die mounted using a COB modular technique. A cavity is milled in the body 1410 for receiving an memory integrated circuit die 1440. Alternatively, the body 1410 may be made of laminated sheets, with the cavity being obtained by stamping out portions of some of the sheets. The die 1440 is attached to a substrate 1420, which is made of any suitable preferably insulative material such as plastic, fiberglass, ceramic, PVC, PVCA, FR4, or any suitable rigid or semi-rigid, non-conductive, and durable material. Alternatively, a conductive material may be used provided insulative structures are provided where necessary for proper electrical operation. Wire bonds such as 1442 and 1444 electrically connect bonding pads on the die 1440 to conductive material that fills vias underlying the contact pads of the contact pad array 1421; contact pads 1422 and 1426 are illustrative. Suitable electrically conductive material for the vias and techniques for filling the vias are well known in the art. A mass of epoxy, plastic or other suitable encapsulation material (not shown) is placed over the die 1440 and the wire bonds, e.g. wire bonds 1442 and 1444, to protect these elements. The body 1410 is made of similar material as the substrate 1420. Alternatively, a more flexible material or a thinner sheet of rigid or semi-rigid material may be used for the body 1410 if desired, provided the substrate 1420, the encapsulation material (not shown), or both provide sufficient rigidity so that the die 1440 and the wire bonds, e.g. wire bonds 1442 and 1444, do not fail due to mechanical stress during normal use.
FIG. 15 shows in cross-section a digital media device 1500 having two memory integrated circuit die 1540 and 1550 mounted using COB techniques. Although dimensionally different, the elements of the digital media device 1500 are similar to the elements of the digital media device 1400. The die 1550 is electrically connected to the contact pads of the contact pad array 1521 (contact pads 1522 and 1526 are illustrative) by a suitable interconnect network laid out on the substrate 1520 between the integrated circuits 1540 and 1550 and the contact pad array 1521 using well known printed circuit board techniques.
FIG. 16 shows in cross-section a digital media device 1600 having two die mounted using a COB direct technique. The COB direct technique is similar to the COB modular technique, but the chips 1640 and 1650 are mounted on the surface of the body 1610 rather than mounted on a PCB which is then inserted into a cavity of the body. The chips 1640 and 1650 are electrically connected to an interconnect pattern (not shown) on the body 1610 of the digital media device 1600 using any suitable technique such as wire bonding, and the chips 1640 and 1650 are encapsulated in any suitable protective material 1630 such as epoxy. Advantageously, the COB technique results in nearly planar major surfaces due to the thinness of the chips 1640 and 1650; compare the digital media devices 300 of FIG. 3 and 1300 of FIG. 13 with the digital media devices 360 of FIG. 3 and 1600 of FIG. 16.
A digital media device incorporates multiple chips or integrated circuits ("IC") to achieve greater memory capacity. When two or more chips or integrated circuits compliant with the NXS protocol as described in the aforementioned Challa et al. patent are used, they preferably share common power, ground clock, and data I/O buses. Static address terminals on the chips or integrated circuits are tied to Vcc or ground as appropriate to impart an address to them so that one of them can be selected in accordance with an address furnished over the data I/O bus. In contrast, the SPI protocol uses separate chip select ports.
In communications, the digital media devices of the family 300 are useful with personal alpha-numeric pagers, two-way pagers, and voice pagers (FIG. 17) for providing enhanced storage capacity. The digital media devices of the family 300 are useful with two way radios, cellular telephones (FIG. 18), and land line telephones for maintaining user specific information such as large telephone directories, telephone logs, outgoing and incoming voice messages for personal answering machines, and outgoing and incoming data storage for facsimile, electronic mail, and transferred files. The digital media devices of the family 300 are useful with modems for storing all of the various forms of data within the capability of the modem. For example, a fax/data/phonemail modem furnished with the capability to receive and store e-mail, transferred files, facsimile messages, and digitized voice data stores this data on the digital media device, which is then removed from the modem and plugged into a personal computer or personal data assistant for retrieval or play-back. Conversely, data is downloaded from the personal computer or personal data assistant to the digital media device, which is then removed from the personal computer or personal data assistant and plugged into a modem for transmission.
In consumer applications, office applications, and desktop publishing, the digital media devices of the family 300 are useful with digital cameras (FIG. 19) for storing pictures and voice recording (e.g. annotations), which are retrievable immediately or later by the camera or a personal computer or other digital media access device, or which may be transferred by modem or digitally to such devices. In addition, the digital media devices of the family 300 are useful with image scanners, digital voice recorders, pen-based tablets, and video capture devices.
In portable computing, the digital media devices of the family 300 are useful with image scanners, and especially handheld image scanners (FIG. 20), for acquiring digital images for later retrieval by a personal computer or other digital media access device, or which may be transferred by modem or digitally to such devices. The digital media devices of the family 300 are useful with computers, especially personal data assistants and laptop personal computers, and even personal data assistants and laptop computers having PC card slots and serial ports through the use of suitable adapters (FIG. 21), for providing significant additional data storage at a lower initial cost, since memory need be purchased only as required and remains useful even as more memory is acquired. Presently, sufficient data storage must be purchased to anticipate future needs, or replaced with higher capacity memory at a later date.
The digital media devices of the family 300 are particularly useful in certain industrial applications such as environmental monitors, industrial process monitors, medical monitors, and computer controlled machinery. For example, when used as a removable storage media for computer controlled machinery, the digital media device stores controlling and profiling data downloaded from a computer and provides access to this information when plugged into the computer-controlled machinery. When used as a removable storage media of a medical data recorder or monitor, the digital media device stores the medical history of a patient, the doctor's instructions to the medical staff, and medication requirements, including amounts, times, special administration procedures, EKG patterns, blood pressure, and other monitored data. In use, the medical digital media card preferably is attached to the patient's clip-board. During a visit, the doctor plugs the medical media device card into a voice recorder and dictates oral instructions, then returns the medical media device card to the patient's clip-board. To administer medication, the nurse plugs the medical media device card into a medication administration and monitoring machine, which plays back any special instructions given by the doctor and records the dose and time of medication, and returns the medical media device card to the patient's clip-board. Any special observations may be dictated for future play-back by the doctor. Other industrial applications include hand held terminals, electronic meters, portable bar code readers, global positioning terminals, talkng sales displays, signal generators and analyzers, flight recorders, and environmental data loggers.
To maintain low cost, preferable the logic for reading, programming, and controlling the memory on-board the digital media devices of the family 300 is implemented in the host or in an adapter, although some inexpensive additional functionality such as error correction may be provided on-board the digital media device itself if desired. Suitable logic for reading, programming, and controlling the memory on-board the digital media device is described in the aforementioned Challa patent. Examples of arrangements in which the logic is located in the host are the voice/data pager of FIG. 17, the cellular telephone of FIG. 18, the digital camera of FIG. 19, and the image scanner of FIG. 20. An example of an arrangement in which the logic is located in an adapter is the laptop computer and PCMCIA flash memory card of FIG. 21. The laptop computer 2010 is any laptop computer having a PCMCIA slot. The adapter 2020 is any ATA PC card containing suitable logic and a socket for receiving the digital media device 2030, and preferably an ATA PC card using the technology described in the aforementioned Challa et al. patent. Such cards are available in various memory capacities from Nexcom Technology, Inc. of Sunnyvale, Calif., under the trademark NexFLASH. Other examples of suitable adapters include serial port interface adapters such as 2040 and compact flash cards such as 110 containing a socket for receiving the digital media device.
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