Abstract:
A method for funding an organizing with cash flows derived from the death benefits of life insurance policies initiated within a bankrupt remote, special purpose entity having the same insurable interest as the organization, by paying the premiums of said policies with proceeds from the issuance of an asset-backed security through the securitization of said death benefits, requiring no use of cash value, no transfer of ownership or beneficiary of said life insurance policies, and providing guaranteed cash flows to said organization while keeping the initial insurable interest intact.

Description:
CROSS REFERENCE TO RELATED PATENTS 
   The present application is related to SYSTEM FOR FUNDING AN ORGANIZATION, Ser. No. 11/753,623, filed May 25, 2007. 
   BACKGROUND OF THE INVENTION 
   The present invention relates to a method for providing funding to organizations such as non-profit organizations, for-profit corporations, and governmental bodies that are seeking to provide alternative funding from their regular sources such as donations, grants, profits or taxes. 
   Organizations raise money in various ways. For-profit and some not-for-profit corporations sell goods and services to generate cash flow to fund their operations. Governments exercise their franchise to tax citizens and businesses to generate revenues. Non-profit organizations such as charities depend on volunteers, donations and grants to carry out their missions. Particularly for charities, but for other organizations as well, there is often a need for an alternative source of revenue, or for a regular, more-dependable source of revenue. 
   Corporations may also need additional revenue to fund retirement and/or health benefit obligations. For example, for-profit corporations have expenses, such as pension expenses, that they may be unable or unwilling to fund with retained earnings. This is particularly so when their competition drives down the price that can be charged for goods and services while their own pension expenses drive up costs. Under these circumstances, profits from current operations may be needed for upgrading capital equipment, sales and marketing, or expanding operations and thus be unavailable for other obligations. As another example, governments may have to raise money to cover liabilities but be reluctant to raise taxes. Still another example, charities may find that the cost to generate donations significantly limits the net amount actually raised, and, accordingly, may be looking for a more efficient way to raise revenue. 
   One way for non-profit and charitable organizations in particular to generate revenues is by persuading a donor to name the organization as a beneficiary of a life insurance policy on the donor&#39;s life. When the donor dies, the proceeds of the policy are paid to the organization. In this relationship, the owner of the policy is insuring is or her own life but naming the organization as a beneficiary. The organization must of course await the death of the insured before it receives any proceeds. 
   Life insurance may be used by for-profit organizations as well. However, in this case, the owner of the policy is not the same one whose life is being insured. Rather, the owner of the policy is the organization and the insured is likely to be a key employee and the organization is seeking to protect its interest in the employee&#39;s value to the organization. For an organization to initiate a life insurance policy on an individual, it must have an insurable interest in the life of the insured individual. The cost of the policy is borne by the organization, and can be a significant additional expense for the organization, particularly if there are many key employees. 
   The concept of an insurable interest is essentially a legal one, one that characterizes the nature of the relationship between two individuals or an individual and an organization and is defined by statute and case law. The person or entity initiating a policy must have an interest in the life of the insured individual in order to be permitted at law to obtain insurance on the value of that individual&#39;s life for financial protection in the event of the insured&#39;s death. The concept of an insurable interest will depend on the laws of the applicable jurisdiction. For present purposes, an insurable interest will simply be defined as a legal relationship between an organization and an individual the existence of which relationship allows the organization to purchase a life insurance policy on the individual&#39;s life. When no insurable interest exists, the present system may be prohibited by law. 
   Relatively recently, there have been a number of attempts to provide funding for an organization by purchasing a group of insurance policies, each one insuring the life of a different individual in whom the organization has an insurable interest, and to fund the cost of the insurance, in whole or in part, with a combination of cash value and death benefits. In some cases, the premiums are financed. However, a review of these programs suggests that they may be risky to the organization and are not as reliable, effective or flexible as the present invention, let alone structured to meet a particular organization&#39;s cash flow needs. Moreover, with so-called investor-owned life insurance (IOLI), stranger-originated (STOLI) or stranger-initiated life insurance, policies are created for the purpose of resale. The ownership of the policies and the rights associated with ownership of the policies are generally transferred by the organization that has the insurable interest to third parties, and are now disfavored. They typically violate the spirit and intent of insurable interest laws in order to reallocate proceeds or excess benefits not required to satisfy debt, to outside third-parties rather than to the organization that initially had insurable interest. 
   Thus an organization appears to have only three practical options when it comes to finding a source of revenue from life insurance policies. It can purchase life insurance on individuals provided that it has an insurable interest on those individuals; it can persuade an owner of a life insurance policy to designate it as a beneficiary; or it can persuade its donors or members to donate current life insurance policies they no longer need. The first option may be cost prohibitive; the second requires the organization to wait for its donor to die, in spite of the fact that its needs for cash may be more immediate and on-going, and the third may also be cost prohibitive, since it usually requires the organization to take over paying the annual premiums. Thus, there remains a need for finding alternative ways of financially protecting and funding organizations. 
   SUMMARY OF THE INVENTION 
   According to its major aspects and briefly recited, the present invention is a method for simultaneously allowing life insurance policies to fund themselves while generating residual cash flow for an organization which has an insurable interest in the insureds&#39; lives. The present method need not use or jeopardize current assets of the organization and does not require a net investment by the organization. Cash flows derived from the death benefits of life insurance policies are sufficient in amount and timing to completely finance the purchase of the policies and, in many circumstances, to also generate a guaranteed cash flow to the organization while the debt for financing the premiums is still being retired. This result is achievable provided that the cost of the program, as defined herein, is lower than or equal to the internal rate of return of the group of policies. 
   An IRR (internal rate of return) is the constant discount rate at which the present value of future cash flows equals the investment outlay. (The realized rate of return, on the other hand, depends upon the amount of premium paid, the benefit amount received, and the timing of both payments.) In the present invention, the IRR is defined in a somewhat different manner. Specifically, in the present invention, a program is defined to run a period of years, such as twenty or forty years. During that program, many but not necessarily all of the individuals in the group of insured individuals will be predicted to die based on applicable mortality tables. An IRR would normally be determined when the last member of the group of insured individuals dies. In the present application, on the other hand, the IRR is not the IRR when the last participant is expected to die, but the expected IRR of the cumulative matured policies up to the time of the retirement of the debt for paying the premiums. Unless otherwise stated herein, IRR has this meaning. 
   The rate required for repaying the debt, including interest, servicing and all other costs associated with borrowing, will be referred to herein as the “borrowing rate” or “cost of borrowing.” Once the IRR exceeds the borrowing rate, the user will know that the debt to purchase the policies (plus other initial costs, if any) can be repaid and cash flows can be provided to the organization. The spread between the IRR and the borrowing rate will determine the achievable size and timing of cash flows to the purchasing organization, both during and after the debt period. The greater the spread between the two, the faster the debt can be retired and/or the greater the revenue to the organization, given a particular population of the group selected. 
   The term “cost of the program” will be used herein to indicate a rate rather than a dollar amount. The cost of the program is the discount rate for the debt structure that is established to finance the premiums on the group of policies, which may include service costs, LIBOR spread, credit spread and also the cash flow to the organization until the debt is retired. 
   If the IRR is not greater than or equal to the cost of the program, the variables used to calculate these two parameters can be adjusted, such as, for example, by being more restrictive in the selection of those participating in the group or by finding policies with lower premiums or by limiting the cash flow to the organization prior to retirement of the debt. Iterative adjustment of these and other variables that affect IRR or the cost of the program, or both, may result in an IRR that exceeds or equals the cost of the program. 
   Moreover, an initially large spread between the IRR and the cost of borrowing allows the organization flexibility in meeting its particular revenue goals. The spread can be used to obtain or increase an initial payment or to obtain or increase annual payments, or to pay off the debt more quickly. Importantly, it can be used to add more people to the group of insured individuals, even people who may lower the IRR and delay retirement of the debt but who will also add to the organization&#39;s revenues through added death benefits. As long as the IRR equals or exceeds the cost of the program, the cash flow will be positive but the size of the gap between them is but one factor in determining the amount of revenue the organization can receive. Other factors include the number of people in the group and the face value of the policies. 
   Simply stated, a major feature of the present invention is that the interaction between the Internal Rate of Return, the cost of borrowing, and the cost of the program determines if a program is viable, if the organizations goals can be met and which funding options are available. 
   A major feature of the present invention is that it can be structured to require no financial resources from the organization or from the insureds. The financing for most nonprofits and some other organizations comes from third parties entirely. (Some organizations such as non-profit corporations, for-profit corporations and government entities, however, may elect to self-finance or partially self-finance, if their alternative investment opportunities so dictate.) Moreover, given the appropriate debt structure and the optimal mix of insured individuals, not only can the present method generate revenue from insurance proceeds after the debt is paid off but also at the debt&#39;s inception and during the debt payoff period. 
   Another important feature of the present invention is that it does not require the policies or rights thereof to be transferred or assigned to the entity financing the cost of the premiums. Rather, a unique feature of this method is that the policies are initially and will remain owned by a “special purpose entity” (SPE) which is also the irrevocable beneficiary. The SPE is established by the organization and is deemed to have the same insurable interest. Only the future cash flows derived from the death benefits of the policies are assigned as collateral to the financing entity and only during the debt period. Other insurance-based funding methods require transfer of ownership of the policies (or at least the ability to transfer ownership and other rights and privileges by assigning the policies as collateral) or use a trust, which may issue certificates of ownership, for example, to ultimately accomplish the equivalent of a transfer of rights and privileges from the initial owner and/or beneficiary. Many require the use of cash build-up within the policies to support the loan structure, and in most cases, to provide benefits to the organization. 
   A unique feature of this method is that it neither requires nor allows for any type of transfer, whether direct or indirect, to a party financing the debt or to a trustee. As a result, the initial insurable interest relationship that is required to initiate the life insurance policies can remain in tact until all policies have matured. The debt structure itself provides further safeguards against violating insurable interest laws by actually prohibiting the transfer of ownership rights, and prevents the revocation of the SPE as sole beneficiary until debt is paid. 
   In a standard securitization process, as opposed to a loan or other conventional debt structure, an originator of financial assets (e.g., loans or receivables) selects a group of financial assets from its portfolio. The originator then sells this pool of financial assets (cash flows) to a special purpose entity (SPE) established exclusively for the asset-backed securities (ABS) transaction. In turn, the SPE typically issues the asset-backed securities to investors. The goal of this securitization process is to isolate the assets, and ensure that payments on the ABS come exclusively from the pool of assets rather than from the originator. To accomplish this with a conventional securitization, the sale of the assets to the SPE must be a “true sale” in legal terms. When a true sale occurs, the financial assets are transferred to the SPE without recourse, and investors in the ABS have the right to the cash flows on the pool of assets, even in the event of the originator&#39;s bankruptcy. The true sale of assets distinguishes conventional asset-baked securities from other types of bonds, which are typically the obligation of the originator. However, the present invention eliminates the need for a true sale of assets because the SPE is the originator and owner of the assets producing the cash flows (i.e., the life insurance policies) and remains irrevocable owner and beneficiary throughout the term of ABS notes. Through the governing documents in the establishment of the SPE, the sale or transfer of ownership of and/or rights to the assets (life insurance policies) is prohibited. 
   Another advantage of an SPE owning the policies and being the irrevocable beneficiary, when the debt structure is based on asset-backed securitization, is that it creates bankruptcy remoteness and therefore protects the note holders in the event the organization goes out of business and it protects the organization in the event of default on the notes. The SPE must at least be a separate legal entity that is established for the purpose of benefiting the organization and protecting the note holders. 
   Another unique feature of this invention&#39;s debt structure is that it can ensure that 100% of excess cash flows go to the organization with whom the original insurable interest existed, because cash flows are used exclusively for repayment of debt, which includes all borrowing cost, and for funding the organization. 
   Another unique feature of the present invention is that the structure can establish the timing of and guarantee a fixed amount of funds to the organization during the debt period regardless of when deaths occur, and without using the cash values of the policies. In fact, even in the unlikely event that the insurance companies never paid, the organization would have received its guaranteed amounts, up through the point at which the program ended. Therefore, funding is guaranteed to be paid to the organization regardless of whether the death benefits of the life insurance are paid. 
   Still another feature of the present invention is that the present invention does not depend on a build-up of cash value of the policies, particularly when financed using debt structures such as asset-backed securities. The cash value if any is not required. The source of revenue required for retiring the debt is simply and solely from the cash flows arising from future death benefit proceeds of the maturing policies. In fact, no or low cash value in the policy type selected is preferred because the premium for such a policy will likely be lower which will improve the IRR and therefore increase the gap/spread. In other funding programs involving life insurance, the cash value of the policies is heavily depended upon for various aspects of those programs, such as providing cash flows to the organization, serving as collateral for the debt, repayment of the debt, and payment of life insurance premiums in the years when there are insufficient death benefits to do so. 
   Another important feature of the present invention is the use, in a preferred embodiment of asset-backed securitization as a debt structure for initiating life insurance policies by funding their premiums. Asset-backed security structures have been used to finance existing receivables. Furthermore, securities have been backed by existing life insurance policies (e.g., Life settlements). In addition, insurance companies have securitized the receipt of their future premiums on existing policies, which are liabilities to them. However, the present transaction, when using asset-backed securitization as a debt structure, is not known under circumstances where it is used to initiate/fund the policies, thereby creating the asset (yet-to-exist life insurance policies) that will produce cash flows to back the security. In the present invention, notes are issued in the ABS market, proceeds of which will pay the premiums, creating the life insurance policies from which the cash flows to back the security are derived. This is a significant feature of the present invention. 
   These and other features and their advantages will be apparent to those skilled in the art of structured finance and funding organizations from a careful reading of the Detailed Description of Preferred Embodiments accompanied by the following drawings. 

   
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
     In the drawings, 
       FIG. 1  is an example schematic of the present method illustrating the components of the present invention, their interaction, and the flow of funds within the method. 
       FIG. 2  is a flow chart illustrating an example of a system for funding an organization, according to a preferred embodiment of the present invention; 
       FIG. 3  is the flow chart of  FIG. 2  illustrating the present system in more detail, according to a preferred embodiment of the present invention; 
       FIG. 4  illustrates the development of a pool of participants, according to a preferred embodiment of the present invention 
       FIGS. 5A and 5B  is a two-part chart showing the breakdown of the final pool of participants of  FIG. 4  after underwriting by age, gender and health, with the top half of the chart shown in  FIG. 5A  and the bottom half of the chart shown in  FIG. 5B ; 
       FIG. 6  is a table showing an illustration of the projected cash flow resulting from a hypothetical group of 1000 58-year-old male non-smokers with standard health and the per policy internal rate of return in the year the policy matures; 
       FIG. 7  is a combination bar graph and line graph showing, as a function of the year of policy maturity, the internal rate of return for the 1000 58-year-old males being shown by a succession of vertical bars and the number expected to die each year following the issuance of the policies being shown by a line; 
       FIG. 8  is a chart showing examples of policy costs for different ages and classifications of insured individuals and the internal rates of return of a group of 1,000 policies; 
       FIG. 9   a  is a graph showing the debt balance as a function of year following implementation of a program according to the present method for a hypothetical internal rate of return of a group of policies and a somewhat smaller borrowing rate for a program developed according to a preferred embodiment of the present invention; 
       FIG. 9   b  is a graph showing the borrowing rate (constant) and the corresponding running internal rate of return of the group of policies as a function of program implementation year for a hypothetical group, according to a preferred embodiment of the present invention; 
       FIG. 9   c  is similar to  FIG. 9   a , that is, it is a graph showing the debt balance as a function of year following implementation of a program according to the present method for a hypothetical internal rate of return of a group of policies and a relatively larger borrowing rate for a program developed according to a preferred embodiment of the present invention; 
       FIG. 9   d  is similar to  FIG. 9   b , that is, it is a graph showing the borrowing rate (constant) and the corresponding running internal rate of return of the group of policies as a function of program implementation year for a hypothetical group, according to a preferred embodiment of the present invention; 
       FIG. 10  is a chart showing total revenues to a charity from various scenarios in which the debt structure and policy premiums are varied, according to a preferred embodiment of the present invention; and 
       FIG. 11  is a chart showing internal rate of return for each age category of a group of 1,000 such policies as a function of the program duration, according to a preferred embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   The present invention is a method, conveniently implemented on a suitably programmed computer that allows the user to develop a positive cash flow from the proceeds of a group of financed life insurance policies. That cash flow is sufficient to retire the debt incurred for the cost of the program and to pay over to the organization excess cash flow proceeds. The payments to the organization can include a part paid before the debt is retired such as an initial payment, and annual payments. The cost of the program is the cost of retiring the debt incurred as a result of financing the premiums on the group of life insurance policies, including servicing costs, other costs of borrowing, and cash flows to the organization. The present method allows the user to (1) determine whether the organization will be able to generate a cash flow that meets or exceeds the cost of the program and (2) to locally optimize the outcome that best meets the organization&#39;s revenue needs. There is no universal optimal cash flow as each organization&#39;s needs may be different and each has a different pool of participants in which it has an insurable interest. Accordingly, the local outcome, that is, the outcome for each organization, may be optimized but that outcome may not be optimal for a different organization. 
   Referring now to  FIG. 1 , there is illustrated an example of a flow diagram of the present invention, in its most preferred embodiment, showing the relationships between the organization, the special purpose entity (SPE) established for the benefit of the organization, the organizations members and the insurance companies providing the insurance on the lives of the members who apply for coverage, as well as those that are involved in the debt structure using asset-backed securitization. The organization and the SPE it sets up for generating funding for the organization both have an insurable interest in the lives of the organization&#39;s members and donors. The SPE will pay guaranteed payments, such as annual payments, and excess cash after its debts are retired, to the organization. It will purchase the insurance policies on the group of members and will receive death benefits from the insurance company when any policy on one of its members or donors matures. It also issues notes to the ABS note buyers in return for payments of principal as the policies mature and interest on the notes according to the market-determined yield curve in effect when the notes are issued, perhaps using a trustee to facilitate and oversee those payments. If a trustee is used, the SPE also pays the trustee fees. The SPE pays the servicing fees to the Servicer. The Servicer monitors the pool of insurance contracts, and ensures that the contractual performance of the parties to the pool (insurance company) is performed satisfactorily, and administers cash flow of death benefits to the SPE. The SPE may provide for contingent cash flows for interest payments, servicing fees, and the guaranteed payments to the organization using a liquidity facility or swap provider to smooth out what might be a “lumpy” cash flow caused by a lag from time to time between actual mortality and expected mortality so that the schedule of payments of interest to the ABS note holders can be met. Importantly, the SPE initiates the policies and issues the notes to the ABS buyers, using the note proceeds to purchase the policies that will generate the cash flows that are securing the notes. These events happen substantially simultaneously, that is, in the same transaction (or mutually contingent transactions). 
   Importantly, the SPE has the same insurable interest as the organization. Same insurable interest means that the SPE may legally purchase life insurance on a group of individuals and that the organization could purchase life insurance on that identical group of individual because the lafter has an insurable interest in the lives of the individuals of that group. There may otherwise be differences in the insurable interest the SPE has compared to that of the organization, or not, under prevailing law. Finally, and also importantly, the SPE does not receive title to the policies or the beneficial rights in the policies from any other party or transfer title or the beneficial rights in the policies to any other party. Indeed, the debt structure is characterized by requirements that forbid transfer of title by the SPE and revoking the sole beneficial interest in the SPE. 
   The sole source of revenue of the SPE will be seen to be the death benefits, not cash value, and from that source, all costs of the program are paid with all the remainder going to the organization, which total of the remainder is forecasted and guaranteed amounts are known and fixed when the program is established according to the present invention and uses the ABS debt structure. 
   In some cases, the organization may be unable to obtain a positive outcome using the present method. The organization may not have a pool of insurable individuals who together constitute a group of insurance policies that have an IRR higher than the borrowing rate. Other organizations, such as large charitable organizations or other large non-profit organizations such as universities, will very likely be able to generate considerable sums of revenue using the present method simply because they can select, from among their donors, a large pool of insurable individuals for policies with the highest predicted IRR ranges, and the fixed cost of the annual payments to the organization are spread over a larger number of policies. 
   The present invention utilizes a computer-implemented interactive mathematical model to compute the expected IRR/borrowing rate gap and to help the user optimize a funding program for an organization. Any organization may use the present method provided that it has a sufficiently large pool of insurable individuals, preferably 1,000 or more, in whom it has an insurable interest. The organization may be a non-profit organization with memberships or donors, a for-profit corporation that may want to fund a retirement program or a government that may also have unfunded benefit liabilities. 
   The present invention is based on purchasing a group of life insurance policies. The primary requirements of these policies are that (1) their premiums must be relatively low and (2) they insure for the life of the insured or at least throughout the debt period. The best type of policy then would be a policy for the life of the insured and having no cash value build-up. Typically term policies have the lowest premiums because they have no cash value but term policies historically do not insure for the life of the insured but rather only for a limited term. If the policy has cash value that builds up, the cash value may be irrelevant to the program because it is the death benefit that is the only source of revenue required to retire the debt and not the cash value. Therefore, the choice of the policy is determined, first, by whether or not it insures each insured participant until death and, second, does it have a relatively low premium. A useful policy for the present invention is a so-called blended universal policy, which has a larger term component and smaller universal life insurance component. Thus, although it does have a small cash value, its premium is relatively low and it can be structured to insure the insured individual for the life of that individual. Other types of policies may appear or be developed that better meet the two requirements set forth here. 
   Another consideration in the choice of the policy is whether it is a single premium policy. A single premium policy is purchased for a single, initial, lump-sum premium. While this type of policy is not essential to the present invention, financing the premiums of a group of policies is simplified if all policies in the group are single premium. Then a single sum is financed in one transaction, and all the uncertainties and contingencies regarding multiple premium payments over time, such as the possibility of default, can be avoided. 
   The policies are purchased from one or more insurers by the SPE to benefit the organization. The SPE, acting on behalf of the organization, is the sole owner and irrevocable beneficiary of the policies. An SPE is a separate legal entity that is established for the purposes of benefiting the organization. Only the future cash flows derived from death benefits will be provided to the financing entity as collateral for the debt; no other assets of the organization or SPE are required and no other payments need to be made. 
     FIG. 2  provides a general overview of an example utilizing the present method. The flow chart shown in  FIG. 2  illustrates how the program operates to achieve the organization&#39;s goals. The selected mix of individuals, which constitutes the group, is the main factor that determines the timing of cash flows into the model. The selected mix of individuals is responsible for the majority of the cost of the program through the insurance premiums. The timing and amount of the cash flows and the borrowing rate associated with the debt structure are both driven by the life expectancy of individuals in the group and the amount of insurance on each. Therefore, a change in the selected mix of individuals which constitutes a group directly affects all aspects of the present method. Within limits based on the membership of the organization, the mix can be adjusted to change and/or improve the outcome of the program. 
   Cost information, cash flow information and debt structure information are combined mathematically in a financial model to determine the internal rate of return of the policy group and compare it to the borrowing rate and to the cost of the program. If the IRR is greater than the borrowing rate, the select group of insurable individuals, policies and borrowing rate constitutes a set of variables that can at least repay the debt. If the IRR equals or exceeds the cost of the program, the organization is assured of at least some funding. By iteratively adjusting the variables, such as the premium cost and the group mix, the resulting funding to meet the goals of the organization can be optimized. 
   Referring now to  FIG. 3 , which shows the use of the present method in more detail. The use of the present invention thus begins with the selection of a group of individuals with whom the organization has an insurable interest. In a guaranteed issue scenario, a policy can be issued on every member of the initial group regardless of health status, gender, age, etc. So, it is possible that the final group may be the same as the initial group. However, based upon the organization&#39;s goals, even if all applicants qualify for participation, it may be advantageous to exclude a portion of the pool in anticipation that the internal rate of return will need to be improved for the program to generate a positive cash flow. Indeed, there are criteria for the selection of the optimal composition of individuals to achieve a desired result. The composition used may vary depending upon the individuals available from which to draw and the organization&#39;s goals. If the applicants from the group are to be underwritten, the first step is to pre-qualify the initial pool of applicants to find a more suitable and realistic group of likely insurable applicants. 
   Ideally the final group is large, having at least one thousand individuals, and having a distribution of ages, but preferably having a majority of them in the age group from 40 s to 70 s. In the example to be described, the insurance policies are fully underwritten and it is important in this case that all the individuals that are finally selected be insurable and be qualified at least as standard risks from a health standpoint. Standard risk is a term used by insurance companies to characterize those who have acceptable if not exceptional health. Insurance companies generally characterize those with satisfactory health as standard, and those in better or exceptional health as preferred and preferred plus. In some cases, the organization can use life policies characterized in the insurance industry as simplified issue or guaranteed issue so that there will be fewer or no restrictions on participation due to health. 
   A suitable pool then may contain a minimum of 1000 individuals, all participating, all insurable, all willing participants, and most between the ages of 40 to 75. While adjustments may be made to such a pool of individuals, a pool with these characteristics would be a suitable starting group. If the group is smaller than 1000 individuals, the cost of borrowing will likely increase because of the greater uncertainty as to the actual mortality it will experience. A larger group will have less uncertainty, meaning that it will likely have a mortality experience that more closely tracks mortality predictions that apply to that type of group. A group with an age distribution skewed toward younger members will likely have a slower cash flow experience and lower IRR during the debt period. A group with an age distribution skewed toward older members will likely have a faster cash flow experience and may have a higher IRR during the debt period unless the number of elderly members is disproportionately higher, in which case the premium cost will likely be higher, and perhaps prohibitive. 
   The pool of individuals should be insured with policies of reasonable face values, based on the value of the individuals to the organization. In the present example, policy face amounts such as $250,000 or $500,000 are suitable starting points. If the organization is a university with both larger donors and smaller ones, it may use policies with different face amounts for the individuals in the two groups. Combining the information about the individuals in the group, the policy face value information and the appropriate mortality information, the present model yields a prediction of the distribution of cash flow by year. 
   The information about the final group of insurable individuals is used together with appropriate mortality tables, in accordance with the present method, to generate the timing and amount of cash flows into the program. Mortality tables will identify the likelihood that some individuals of each age may die in each year beginning with the first year of the program and continuing until each member of the group is predicted to die. The death of each member triggers payment of a death benefit from the corresponding life insurance policy. The death benefit payment of each policy contributes incrementally to the cash flow. 
   On the other side of the equation, there are costs to be identified. There are initial and on-going costs. The initial costs include the cost of purchasing the policies, debt underwriting fees and initial payments, if any, to the organization. The on-going costs include interest on the debt and periodic payments to the organization, if any. A source of financing is selected that will most likely finance the cost of the program from the death benefits of the policies. The debt structure used for financing will have a cost of borrowing (which may include credit spread, LIBOR spread, servicing cost) indicated by a rate. 
   The interaction of the debt structure, cash flow from the policy death benefits and initial and ongoing costs is difficult to predict without running a calculation using the present financial model, implemented using a suitably programmed computer, to determine whether the given set of inputs will result in a viable program; i.e., one that results in positive cash flow to the organization while retiring the debt in a finite amount of time. The outcome of this first calculation gives the user an initial idea as to whether the program is viable and, if so, the degree to which it is viable. Viability is achieved when the IRR exceeds the borrowing rate. By adjusting the inputs, the outcome may be improved. When the IRR equals or exceeds the cost of the program, the initial objectives of the organization are met: it can receive net proceeds. The gap between the IRR and the cost of the program may be further increased by adjusting variables such as the pool of participants, the debt structure, and the policy premiums. Once the gap is as large as it can be, the user can begin to make it smaller by increasing the number of participants and/or the payments to the organization until the gap between IRR, with the additional participants, and the cost of the program, now revised, is near zero but still at or above zero. The process of optimization is an interactive loop which can produce a final outcome that is close to meeting or even exceeding the organizations goals. 
   The borrowing rate and structure is of great importance. Any source of financing that provides low rates, such as, to give one example, the asset-backed securities market, should be considered. Additionally, devices such as surety wraps can be used to protect against those circumstances in which actual mortality experience lags predicted experience. Swaps may be used to smooth lumpy cash flows derived from the uncertain timing of cash flows arising from death benefits, and/or to provide fixed and guaranteed cash flows to the organization during the debt period. 
   In the present example, however, in order to maximize benefits to the nonprofit organization (i.e., borrowing at the lowest available rates), the default debt structure is assumed to be based on notes sold in the asset-backed securities (ABS) market. Simply put, ABS buyers lend funds at very competitive rates because they are backed by specific pools of assets. Usually the securities will make floating interest payments semiannually with a coupon formula based on the six-month LIBOR rate plus a predetermined credit spread. The principal and interest in this case are paid from proceeds of death benefits received as the individual policies mature. The asset-backed security structure is further characterized by payments of principal following payment of death benefits. 
   Another important feature of the present invention is that the lender (e.g., ABS note-holders) is indifferent to the pool&#39;s realized mortality rate over the program&#39;s life. The debt structure has a defined schedule of market-determined interest rates, based on an applicable yield curve and has a guaranteed schedule of payments. From the lender&#39;s perspective, the pay down of the debt&#39;s principal is uncorrelated with macroeconomic variables like interest rate. In contrast, other insurance-based funding programs benefit from an accelerated mortality rate. For example, an investor in an STOLI program retains an equity stake in the life insurance pool (like an owner of common stock) in that the return on the investment depends directly on the pool&#39;s realized mortality rate. Graphically put, if the pool&#39;s mortality rate is faster than expected, an STOLI investor benefits from the faster payoff of the death benefits. In sharp contrast, lenders in the present program do not have an equity claim and are therefore not owners. Like all lenders, their primary concern is the return of the amount lent and interest. The interest payments they receive are fixed by contract and, regardless of the pool&#39;s realized mortality rate, cannot exceed the contract amount. In addition, there is also prepayment risk to the ABS note-holders, in the event of higher than expected mortality. 
   Another important feature pertains to the organization itself, since the payments (i.e., upfront lump sum and annual periodic payments) are guaranteed to the organization using the present invention; they are likewise indifferent to the pool&#39;s realized mortality rate during the debt period. Since payments to the organization are fixed in the present program, the organization is actually better off while the insured individuals are alive since the organization is also benefiting from their ongoing contributions. Thus the present invention eliminates the specter that haunts schemes for funding organizations using insurance that the lender or the organization is “gambling on death.” 
   It is also important to note that the pay down of the principal is uncorrelated with a change in market interest rates because there is no causal linkage between interest rates and mortality rates. This is an appealing feature for investors compared to typical ABS securities, which pay back principal faster when rates are lower, which in turn forces ABS investors to reinvest at lower interest rates. When ABS securities are backed by the guaranteed cash flows derived from the death benefits of a pool of life insurance policies, they do not possess this unappealing property. 
   On the close of the transaction in which the group of policies is purchased, the organization will enter into a single currency interest rate and liquidity swap to provide liquidity for servicing the interest due on the ABS notes, for servicing and trustee fees and the annual payments to the organization, and for hedging the underlying interest rate risk associated with floating rate notes. At closing, the timing and amount of funding to the organization will be determined, and the swap provider may make the initial payment, if any, to the organization. The life insurance policies and securities will become effective substantially simultaneously. 
   The information regarding the cash flow distribution by year based on the selected pool of individuals, the debt structure and borrowing rate, and the costs of the program are combined in a straight-forward mathematical way to project cash flows and thereby predict if and when the received death benefits can retire the debt and produce a net positive cash flow to the organization. This will occur if the internal rate of return of the group of policies is greater than or equal to the cost of the program during the term of the debt. The larger the initial difference between the IRR and the cost of the program, the sooner the policy debt can be paid off and the larger the overall benefits may be to the organization. 
   The IRR of a single policy is the constant discount rate that makes a future cash receipt equal to the investment outlay. In calculating IRR for a group of policies, the initial outlay, namely, the single lump sum premium for the group of policies (in the example used), is equal to the sum of the discounted future cash in each year (or other period of time). The future cash in year j is equal to the face value of all of the policies predicted to mature in year j discounted to the present. The equation for determining IRR is as follows:
 
0= C   0   +C   1 /(1 +R )+ C   2 /(1 +R ) 2   +C   3 /(1 +R ) 3   + . . . C   n /(1 +R ) n  where
 
C o  is the initial outlay (a negative number), C 1  through C n  are the policy proceeds (positive numbers), n is number of the interval (year) when the debt is retired and R is the internal rate of return (IRR).
 
   In the equation for IRR of the group of policies during the desired term of the debt, the initial outlay is known; the cash flow for each year of the future is predicted from the applicable mortality tables given the underwriting information about the final group of insurable individuals. Therefore, the only variable not known is IRR, which can not be solved for analytically, but the IRR can be calculated numerically. 
   Based on an initial calculation of IRR and knowing the cost of borrowing from the tentatively selected debt structure, the organization will know whether it can use the present method for funding itself or, alternatively, that that prospect may be in doubt. In either case, however, subsequent iterations may be done using different values for the input variables to improve the results. Many of the variables that affect the outcome can be adjusted in such a way as to improve the outlook for funding that meets the organization&#39;s needs. The user of the present computer-based and interactive model may iteratively adjust the values of the variables to locally optimize the program. 
   There is no universally optimal result, however, since some organizations need larger initial cash infusions or larger year-to-year infusions and each organization will have a different pool of those with whom it has an insurable interest from which to choose. Given an organization&#39;s needs for funding, and in particular its needs for near-term and annual funding, and its flexibility in tailoring its group of insured individuals, it will be possible to improve the initial outcome, perhaps significantly, by repeated iterations of the basic calculation. With sufficient patience, the funding needs of an organization can be optimized for a given organization. 
   As stated above, the process begins with the selection of a group of individuals from among those with whom the organization has an insurable interest. This group of potentially insured individuals is first pre-qualified to limit it to those who are willing to participate and to those who are more likely to pass underwriting. Those that are candidates after pre-qualification are subject to underwriting approval to generate the final group of insurable individuals. 
     FIG. 4  illustrates a hypothetical example of this pre-qualification step. The illustration shows the reduction of an initially larger group to a smaller pool of candidates. For simplicity in the example, a charitable organization has the stated goal of maximizing the cash flow to the organization both on an annual basis while the debt is outstanding and on a cumulative basis after all policies have matured. The charity&#39;s intent can be met by the use of life insurance on its members to protect the organization from the loss of this important asset. Policies may typically have a face value of $250,000 and $500,000. 
   If a sufficient number of volunteers are available within an appropriate age range, the organization will find itself to be a suitable candidate for the present program. A basic group census is used for initial projections. If the group is very large, a subset of the group may be used provided that the subset has sufficient number of willing, insurable participants and the age range includes many participants between 40 and 75 years of age. 
   In order to evaluate whether the individuals who are willing to participate form a suitable group, information such as birth date, gender, tobacco usage, etc. is obtained to sort the individuals into different categories. Sorting the initial group into categories is required for performing the initial calculation on cash flow and is also helpful for subsequent iterations of the calculation, as it allows the initially selected group to be modified if necessary to improve IRR. 
   In the example, 5000 individuals are members of the organization. Of those 3444 volunteers are available and willing to participate. Those whose health is suspect, or whose life insurance premiums are likely to be exceptionally high may also be excluded. Therefore, tobacco users are eliminated. The remaining 2984 are not tobacco users and are sorted by age and gender. Individuals over age 80 are then excluded because their expected IRRs are not as advantageous to the program as other age groups during the debt period, so the number of volunteers who do not use tobacco and who are not over 80 is now reduced to 2619, 2000 of them male and 619 of them female. These 2619 individuals will be subjected to underwriting to determine whether their health is categorized as standard, better or worse. 
   Of the 2000 males and 619 females, 1200 males and 407 females fall into one of three health categories, namely, standard, preferred, or preferred plus. The other 1,012 individuals are eliminated because their health is worse than what is required to meet the standard classification. Remaining are 131 male non-tobacco users who are in the preferred plus health category; 155 male non-tobacco users who are in the preferred health; and 914 male non-tobacco users who are in the standard health category. There are 50 female non-tobacco users who are in the preferred plus health category; 57 female non-tobacco users who are in the preferred health category; and 300 female non-tobacco users who are in the standard health category. All are 80 years of age or younger and all are volunteers. 
   Pre-qualification thus means obtaining an initial estimate of those willing to participate, their demographic information, and sufficient health information to believe that these individuals are likely to present, for this example, at least standard health risks. All in the potential population can be contacted or, if the potential pool is very large, only a portion of the pool will be needed to fund the organization so only that portion will need to be pre-qualified. 
   Those who have been pre-qualified are subjected to the underwriting step to determine the policy premium. In the example, this process is largely one of categorizing the individuals into four health categories: preferred plus, preferred, standard, and less-than-standard. Those categorized as less-than-standard will not likely be utilized because the insurance is either unavailable or the premium costs are prohibitive. Those remaining are likely participants and policy premium rates are assigned to each health risk group and by gender and age. For example, at a given age there will be one rate for preferred-plus females and a different rate for preferred-plus males. 
   In the example illustrated in  FIG. 4 , full-underwriting will be conducted on each individual who has been pre-qualified. Some will not meet requirements for health and will therefore be eliminated from the group. For the sake of this example, reasonable assumptions regarding insurability are applied to all age categories, because only a certain percentage of the potentially insurable group of individuals will be acceptable at any health classification. For this example, health classifications that are less than “standard” are excluded. Of those who pass through underwriting, a certain percentage will be issued polices at classifications above standard. While there are many classifications used in practice, for the purposes of illustration we will only use “Standard”, “Preferred” and “Preferred Plus”. The older the individual, the less likely they are to achieve a higher rating or classification with Preferred Plus being the highest. 
   The advantage of pre-qualifying members of the group and subjecting them to underwriting is to make their collective mortality more predictable. For very large groups (i.e., much greater than 1000 individuals), this advantage is not as great as for smaller groups (i.e., approximately 1000 individuals or less) 
   Results from pre-qualification and underwriting are combined with appropriate mortality tables to develop a predicted cash flow model. 
     FIGS. 5A and 5B  comprise a single table shown in two parts containing a breakdown of information relevant to mortality of those participants selected as shown in  FIG. 4  following underwriting. The numbers of male and female participants who have undergone pre-qualification are listed by age in the first two columns. The next five columns identify the percentages in each age category who passed underwriting together with a breakdown of the percentages who fall into the category of standard health and above standard, with a further breakdown as to those who are in the preferred category and those who are preferred plus. 
   The remaining columns break down the number of participants by gender and health category in each age group. Totals are given at the bottom of the second half of the chart, in  FIG. 5B . Depending upon the group pre-qualification information and the results of the underwriting step, appropriate mortality tables are selected to predict the mortality of the participants based on their ages, genders, and current health categories. In this example, because complete underwriting is taking place, the “Preferred” version of the 2001 Valuation Basic Table (VBT) of the American Council of Life Insurance interim tables are used as a starting point. These tables can, with relatively small margins of error, predict the timing of deaths. 
   The predicted mortality is then combined with information about the face value of the policies and the information about the group of individuals to be insured to develop a cash flow for input to the financial model (see  FIG. 3 ). Then the cost side is developed starting with the cost of the premiums for the policies on this group of insured individuals. In  FIG. 3 , it will be seen that the policies are selected (or developed in cooperation with a particular insurer) that will provide the lowest premiums in insuring the insured individuals for the duration of their lives. 
   The benefit amount or face value of the life insurance policy is selected based upon the projected, estimated value of an individual to the organization Additionally, policy face amounts for the individuals within a group do not all need to be the same. The face amount may vary from one individual to another depending on the goals of the organization; available financing; insurability; and insurable interest. In the example, face values of 250,000 and 500,000 are used. 
     FIGS. 6 ,  7  and  8  illustrate various aspects of this process.  FIG. 6  is a chart showing the mortality distribution and projected cash flows for a group of 1000 men at age 58 when their policies are issued. The individuals of this group are all rated as “standard” and are non-smokers. The policy premium is $141,009.10 for a $500,000 policy when the premium is paid as a lump sum upon issuance of the policy. In the first year, from an actuarial standpoint, two of the 1000 policies are expected to mature, generating $1,000,000 in proceeds. 
   The internal rate of return (IRR) for just these two policies is 254.6%. The IRR is the constant discount rate at which the present value of future insurance proceeds exactly equals the initial outlay for the policies. It will be seen that the IRR for subsequent policies drops rapidly in subsequent years. When the peak projected number of annual deaths occurs, about 44 deaths in the 25 th  year of the policies, the IRR is 5.2% in the example shown. 
   Determining the IRR for the group of policies rather than individual policies, requires setting the summation of the discounted cash flows equal to the initial investment and then solving for the IRR used to discount the cash flows. The IRR for this group of 1000 policies, that is, when all are predicted to mature, is 5.97%. 
   The IRR information for the policies that mature in each year is shown in a bar graph in  FIG. 7 . Superimposed on the bar graph is a plot of the number of deaths per year, which generally defines a bell curve peaking at year 25. 
     FIG. 8  shows a chart of representative premiums for males ages 28, 38, 48, 58, 68 and 78, having different levels of health as indicated by the designator. In that designator, M stands for male, S for standard, NT for no tobacco, P for preferred, PP for preferred plus. Accordingly, a code of MSNT denotes male, standard, non-tobacco; MPNT denotes male, preferred, no tobacco. Also shown is the IRR for each category, assuming 1000 policies are issued per category, during the term of the debt. The premium for a life insurance policy is a function of many factors including, but not limited to, age, gender, health, underwriting, expected mortality, insurance company, and the insurance product being used. It will be readily noted that in this example, generally, the highest IRR in each age group during the term of the debt is for preferred plus with no tobacco use. However, of those, the highest IRR during the term of the debt is for males who are at age 68 because they have the most favorable trade-off between lower premium and shorter life expectancy. In this hypothetical example, males age 58 have the next highest IRR and males age 28 have the lowest notwithstanding low premiums but because they have the longest life expectancy. Accordingly, for this example, groups with larger numbers of those in the age groups 40s-70s can be expected to generally have the highest IRRs during the term of the debt and, given appropriate debt structure, are the most likely to be able to generate death benefits that are able to pay off the costs of the present program. 
   Returning now to  FIG. 3 , there are costs associated with the present program in addition to the initial premium on a large group of life insurance policies, although premium is the major one. The organization may want an initial payment and annual payments that at least provide some minimum level of funding. A good starting point for estimating the initial payment and annual payments is $500 per year, per insured individual. The gap between IRR and borrowing rate may allow a little more or a little less and the amount may also vary depending on the needs of the organization. 
   There may be administrative costs and set up costs. These costs and the cash flow associated with the proceeds of insurance policies that mature as a function of time are combined with the debt structure. In the example used, this organization&#39;s goal is to receive at least a minimum initial payment of $1,000,000 and subsequent minimum annual payments each preceding year in the amount of $500,000 while the debt is outstanding. Thereafter, all of the policy proceeds are paid to the organization. As a result, $1,000,000 is included in the initial cost and $500,000 is included in the ongoing cost. 
   The debt structure must be suitable for long term debt payment, perhaps taking several decades before the debt is fully retired. The future cash flows which are derived from death benefits are used to collateralize the debt. Debt structures that are suitable include for example, use of asset-backed securitization. Borrowing rate information for different types of debt structures can be found in the usual sources of information on current rates available from financing institutions or by consulting with financing institutions. 
   Once the various input factors and debt structure information is assembled, a suitably programmed computer can run the calculation to determine if the debt can be retired from the cash flow. The threshold goal is to be able to retire the debt. Additionally, the goal is to retire the debt at a time before all of the insurance policies have matured. This goal will be achieved if and when the IRR is greater than the borrowing rate. Then when the funding to the organization prior to the retirement of the debt is added to determine the cost of the program, the IRR must be equal to or exceed the cost of the program. The gap between the IRR and the cost of the program can be further increased by adjusting the input variables iteratively. Once the gap has been maximized, it can be reduced by adding additional insured individuals, thus bringing down the IRR but adding additional policy proceeds, and/or by increasing the payments made to the organization, in accordance with the organization&#39;s objectives, before the debt is fully retired, thus increasing the cost of the program. 
     FIGS. 9   a ,  9   b ,  9   c , and  9   d  illustrate two examples of the use of the present method and model. In the first example, illustrated in the two graphs presented in  FIGS. 9   a  and  9   b , respectively, are for an organization in which the IRR of the mix of policies of its insurable group is greater than the borrowing rate. In the second example, illustrated in the equivalent two graphs of  FIGS. 9   c  and  9   d , respectively, the IRR of the same organization is less than the borrowing rate. The IRRs are the same but the borrowing rate of the two examples are different and thus, importantly, the gap between the IRR and the borrowing rate is different. The difference between the two borrowing rates is small, less than 1%, but the effect of this small difference is very striking. Comparing the first chart for each example ( FIGS. 9   a  and  9   c , respectively), there is shown the increase in the debt balance in the initial years of the program although the one with the higher borrowing rate has a larger increase. Both show the debt balance begins to decrease as the cash flow from proceeds of the life insurance increase. However, the debt balance continues to drop to zero, indicating a paid-up debt between year 28 and 29, for the first example illustrated in  FIG. 9   a . The debt balance starts to climb again in the second example ( FIG. 9   c ) as the proceeds of the declining number of maturing policies are insufficient to pay the remaining balance of the debt, and the debt with accruing interest begins to increase again, and is ultimately never paid in full. 
     FIGS. 9   b  and  9   d  illustrate this contrast in a different way, one showing the IRR and borrowing rates versus policy year. The borrowing rate is constant at just under 6%. The cumulative IRR for the group rises rapidly from very negative values in the early policy years but reaches its asymptotic value at a level higher than the borrowing rate in the first example, crossing the line indicating the value of the borrowing rate when the debt is paid off. For the second example, the IRR never exceeds the borrowing rate and reaches its asymptotic value at a level just below the higher borrowing rate, indicating that this debt is never paid off. 
   In the event the organization using the present method fails to obtain an IRR that is higher than the cost of borrowing for its group of policies, it may revise its initial choices of input variables and perform the calculation several more times to see if, through repeated iterations, it can achieve a higher IRR than the cost of borrowing. 
   There are many variables that can be changed. For example, the initial sum paid to the organization may be decreased, increased, or eliminated. The annual sum may be decreased, increased, or eliminated. Cost of the policies may be evaluated to see if there are lower cost alternatives such as using multiple insurers, a variety of insurance products or blended insurance products. The pool of policies may be reconsidered, such as, for this example, by replacing younger members with healthy older members, replacing less healthy members with healthier members, increasing the number of members in the age range 40s-70s relative to those outside of that age bracket, etc. With respect to debt structure, looking for lower underwriting fees, timing the program when interest rates are lower, negotiating more favorable up-front and service fees, are several examples of ways to reduce the borrowing costs. 
     FIG. 10  illustrates hypothetical parametric studies in which the cost of borrowing was lowered by reducing borrowing rates based on those available in the market and in which the IRR was increased by shopping for more competitive policy premiums. All other variables remained the same. In the base case, a total of $46 million dollars was returned to the charity. In subsequent iterations, the amount returned to the charity was increased to $208 million, more than a four-fold increase, by a combination of a borrowing cost that was 50 basis points (0.5%) lower and an insurance premium reduction of 5%. 
     FIG. 11  illustrates clearly how the selection of a population and the duration of the program affect the IRR.  FIG. 11  is a chart showing the IRR associated with each age grouping of male non-smokers in standard heath as a function of the duration of the program. A review of this chart will show that the IRR increases for each age group the longer the program lasts. This is simply because the longer the program lasts, the more of those in that age group are likely to die during the program. The more that die, the greater the total life insurance proceeds that are received; hence, the IRR increases accordingly. 
   It will also be evident from the chart that the older the age category, the less the IRR increases with the increasing duration of the program. In fact, for those beginning in their later 50s and older, the IRR does not increase as much over time as with the younger age groups (but certainly cannot decrease) because those in the older age groups are even more likely to have died during the program. Note, importantly, that for some of these older age groups, the IRR is among the highest of all the age groups. Among the very oldest, the higher initial premium for the policy along with shorter life expectancies begins to reduce the IRR compared to those in their mid-50&#39;s and their 60&#39;s. Accordingly, in selecting a population for the present program and in particular for a program of a given duration, it is important to select a larger number of individuals in age groups in their 40&#39;s to about age 75, because these individuals will have the highest individual IRRs, based on the relationship between their premiums and life expectancies, and will more significantly help to guarantee the present program&#39;s chance of returning cash to the organization than those in other age groups. 
   The combination of lower borrowing costs and lower premium costs increases the gap between the IRR and the borrowing cost. This larger gap can be used to give the organization more flexibility in regards to funding options. For this example, if the annual amount paid to the charity were increased from the base case $500,000 to $2,000,000, the total amount netted by the charity is lower than $208 million but is still $130 million. A large gap between IRR and borrowing rate can also be used to expand the group, for example, by adding younger members to the group in order to provide additional insurance proceeds in later years; or by adding older members to provide increased cash flows in the earlier years; or a combination of both. While for a given size group, the larger the gap, the more money that will be returned to the organization, increasing the size of the group (assuming the increase does not eliminate the gap), the greater the revenue to the organization. Each of these changes would extend or shorten, respectively, the debt retirement period. However, the debt repayment is preferably no longer than 50 years and is preferably much shorter than that to keep borrowing costs low. 
   The present method is successful to the extent that the IRR on the group of policies equals or exceeds the cost of the program. It should also be noted that the cost of the program includes all costs associated with the program, which in turn includes the amount of initial and annual cash payments to the organization. If the internal rate of return is less than the cost of the program, then alterations must be made to the variables used in the present model until success is achieved. Simply put, in a low interest rate environment, it is possible to select a combination of insurance policies whose expected future cash flows from death benefits exceed the cost of funding the debt incurred for purchasing the policies and for the funding of the initial and annual cash flows to the organization. Furthermore, the user may achieve increased revenue for its particular organization&#39;s funding needs by varying the input iteratively and evaluating the output until funding revenues are maximized. 
   It is intended that the scope of the present invention include all modifications that incorporate its principal design features, and that the scope and limitations of the present invention are to be determined by the scope of the appended claims and their equivalents. For example, in the foregoing description, the organization is described as purchasing policies on the pool of individuals in whom it has an insurable interest. However, instead of the organization making the purchases of policies directly, a subsidiary or other SPE of an organization may act on behalf of the organization as the active party in implementing the present method so long as the SPE&#39;s purpose is to provide funding for the organization. It also should be understood that the inventive concepts herein described are interchangeable and/or they can be used together in still other permutations of the present invention, and that other modifications and substitutions will be apparent to those skilled in the art from the foregoing description of the preferred embodiments without departing from the spirit or scope of the present invention.